EPA-Enforcement Alert: Flaring and Uncontrolled Sulfur ... · laring is an engineering practice that provides for process equip ... Ensure there is adequate ca

Enforcement Alert

United StatesEnvironmental Protection and Compliance (revised)Agency Assurance (2248A)

Office of Enforcement EPA 300-N-00-014

Enforcement Alert Volume 3, Number 9 Office of Regulatory Enforcement October 2000

Frequent, Routine Flaring May Cause Excessive, Uncontrolled Sulfur Dioxide Releases

Practice Not Considered ‘Good Pollution Control Practice’; May Violate Clean Air Act

About

Enforcement Alert “Enforcement is published periodically by the Office Enforcement educate regulated important enforcement trends enforcement actions.

This information should help the anticipate violations environmental law that could otherwise lead to enforcement action. Reproduction and wide dissemination publication are encouraged.

For information on obtaining additional publication, contact the editor listed below.

Eric V. Schaeffer Director, Office of Regulatory Enforcement

Editor: Virginia Bueno (202) 564-8684 [email protected] (Please Email all address and name changes or subscription requests for this newsletter.) Continued on page 2

Flaring is an engineering practice that provides for process equip

ment to immediately release gases to a

This publication is found on the Internet at http://www.epa.gov/oeca/ore/enfalert

in a manner consistent with good air pollution practices for minimizing emissions. New “clean fuels” requirements will lead to the removal of even greater

Frequent and routine use of flares may not be good air pollution control practice for reducing emissions. (Photograph courtesy of Kaldair Inc.)

device (a flare) where they can be quickly and safely incinerated. flares is a good engineering practice because flares can p reven t damages, fires and e x p l o s i o n s , and injuries employees. Flaring also converts noxious and odorous gases re-leased in emergencies to less hazardous and objectionable emissions by the burning of the gases.

But EPA investigations suggest that flaring frequently occurs nonemergency situations or is used to bypass pollution control equipment. in unacceptably high releases of sulfur dioxide and other noxious pollutants and may violate the requirement that companies operate their facilities

Editor’s Note: To clarify sulfur dioxide re-porting requirements, this issue contains slight revisions to the sections, “Diagnosing, Preventing Excess Flaring,” located on page 3 and quirements for Flaring Incidents” on page 4. sue.

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Enforcement Alert

Continued from page 1

amounts of sulfur from feed stocks. Companies should ensure they have ad-equate capacity to treat these pollutants without resorting to excess flaring.

Good pollution control practices include:

1. Procedures to diagnose and prevent malfunctions; and

2. Adequate capacity at the back end of the refinery to process acid gas.

At petroleum refineries, flares are used in a variety of process areas to prevent hydrocarbons and waste gases from being released directly to the atmosphere. Since hydrocarbons are the primary product at refineries, companies should make every effort to avoid sending their products up in flames.

Flares, however, are also used to combust acid gas—a highly concentrated waste stream of hydrogen sulfide gas (up to 90 percent pure)—and sour water stripper gas (about 30 percent pure).

Sulfur Recovery Plants (SRPs) normally process hydrogen sulfide gas and sour water stripper gas. A sulfur recovery plant is a refinery process for producing elemental sulfur for sale but is also a part of the refinery’s air pollution control systems. The process converts 95 percent or more of these hydrogen sulfide gases into elemental sulfur while reducing emissions to insignificant levels. Use of a flare for combusting acid gas instead of processing it in the SRP produces very large uncontrolled releases of sulfur dioxide (SO

2) and effectively bypasses the per

mitted and monitored SRP emission point. While the flare is designed to pre-vent the direct release of the very toxic

and odoriferous hydrogen sulfide during malfunctions at the SRP, EPA has documented situations of regular or routine use of flares for acid gas incineration instead of the expected reliance on the flare only for emergencies.

One day of acid gas flaring can easily release more SO

2 than is released in

a single year of permitted SRP activity. On numerous occasions, EPA has uncovered information on acid gas flaring incidents that shows that 100 tons or more of SO2 can be released in such flaring within a 24-hour period. A moderately sized Claus sulfur recovery plant (approximately 100 long tons of sulfur recovered per day capacity) that is subject to the New Source Performance Standards and properly operated with its pollution control device should emit no more than 250 parts per million of SO

2, a rate that corre

sponds to a little less than 100 tons annually.

Health Dangers From Sulfur Dioxide

Flaring H2S can produce high am

bient concentrations of SO2. Short-term

exposures to elevated SO2 levels while

at moderate exertion may result in reduced lung function accompanied by such symptoms as wheezing, chest tightness, or shortness of breath in asthmatic children and adults. Other effects associated with longer-term exposures to high concentrations of SO

2, com

bined with high levels of particulate matter, can result in respiratory illness, alterations in the lungs’ defenses, and aggravation of existing cardiovascular disease. Those at risk include individuals with cardiovascular disease or chronic lung disease, as well as children and the elderly.

Acid Gas Flaring Routine or nonemergency “flaring

The NSPS defines “fuel gas” to be any gas generated and combusted at a refinery and identifies flares as NSPS affected facilities. A’s letter to Koch Petroleum Company (Dec. 2, 1999) provides a detailed explanation of the various types of gases subject that are to NSPS requirements because they meet the definition of fuel gas (see http://www.epa.gov/oeca/ore/aed).

The NSPS exempts flaring of fuel gas from the standards for sulfur ox-ides and monitoring requirements only when there is a process upset or an emergency malfunction. (40 C.F.R.Section 60.104(a)(1)). glish” exemption applies only to true emergencies, and the Agency expects other flaring to be monitored and comply with applicable emission limits.

EPA believes that many affected facilities at petroleum refineries may not be in compliance with applicable NSPS requirements (fuel gas monitoring and emission limits for fuel gas combustion devices) because of their routine reliance on flaring to control releases of hydrocarbons. The Agency also believes that, as with acid gas flaring, good air pollution control practices include investigating the causes of flaring events and taking corrective action to avoid or reduce the probability of their recurrence. One way to address these potential compliance issues may be through the proper de-sign, operation and maintenance of flare gas recovery systems.

Hydrocarbon Flaring Considered Fuel Gas Combustion Subject to NSPS

EP

This “plain En

Continued on page 3

October 2000 2

Enforcement Alert


of acid gas” is directing that gas away from the recovery plant, combusting it at a flare and releasing sulfur dioxide to the atmosphere. Acid gas flaring is not a federally permitted operation and should typically only occur during a malfunction (a “sudden, infrequent, and not reasonably preventable failure of equipment or processes to operate in a normal or usual manner”) (40 C.F.R. Section 60.2). In EPA’s experience, frequent and repetitive acid gas flaring is often not due to malfunctions. Acid gas flaring that is routine or preventable violates the NSPS requirement for operating consistent with ‘Good Air Pollution Control Practices’ to minimize emissions at refineries with NSPS fuel gas combustion devices and affected facilities including SRPs (40 C.F.R.Section 60.11(d)).

Chain Reaction: Upstream Upsets May Result in Downstream Malfunctions

Properly designed, operated and maintained SRPs can typically receive and treat all acid gas produced at the refinery (most also are designed to treat sour water stripper gas). These gases should not be flared except under emergency or malfunction conditions.

Upsets in upstream process equip-

The Agency also believes that, as with acid gas

flaring, good air pollution control practices include investigating the causes

of flaring events and taking corrective action to

avoid or reduce the probability of their

recurrence.

ment may result in hydrocarbons or other contaminants entering the acid gas stream. Hydrocarbons can be very disruptive to the short- and long-term operation of the SRP. Historically, not much effort has been put into investigating and correcting the root cause of contamination or upsets. Instead, incidents have been simply reported as “malfunctions.” EPA, believes that repeated malfunctions for the same cause, generally, could be predicted and pre-vented. If flaring results from a preventable upset, EPA believes that it does not represent good air pollution control practices and that it may violate the CAA.

Diagnosing, Preventing Excess Flaring

Repeated or regularly occurring incidents of flaring can be anticipated and should not be classified as ‘malfunctions.’ For example, regularly switching between high and low sulfur crude may cause fluctuations of the acid gas feed to the SRP. This can create operational problems for the SRP and/or its pollution control equipment, resulting in a perceived need to flare. These up-sets should be addressed through improved operational control systems, improved and frequent training of opera-tors, and continued optimal performance of the SRP, not by bypassing or flaring acid gas and sour water strip-per gas.

Another cause of flaring is inadequate capacity of the SRP and its associated tail gas unit (TGU) to process all the acid gas at the refinery. Refineries should ensure that their units have the capacity and can handle variable volumes that may occur during different production levels.

Refineries should implement the following procedures to ensure that flaring results only from a true emergency or malfunction:

BP Amoco Reduces SO2 Emissions from Flaring Nearly 75%

From 1993 to 1995, the BP Amoco facility in Oregon,

Ohio, experienced an annual average of 16 flaring incidents and released approximately 180 tons of SO

2 . Under the procedures out-

lined in a Consent Decree with EPA, BP Amoco has been able to reduce that amount to an insignificant number (three flaring events in 1999 released a total of 49 tons of SO

2) and each event was attrib

utable to a true “malfunction” as defined in NSPS. This was accomplished through equipment and operational changes that eliminated the root causes of such flaring. The protocol in the consent decree (http://www.epa.gov/oeca/ore/aed) serves as a model in balancing the concerns of Good Engineering Practice and good Pollution Control Practices for any flaring of acid gas or sour water stripper gas.

� Conduct a root-cause analysis of each flaring incident to identify if any equipment and/or operational changes are necessary to eliminate or minimize that cause so as to reduce or avoid future flaring events. As appropriate, corrective measures should be taken and implemented. If the analysis shows that the same cause has happened before, the incident should not be considered a malfunction and corrective measures should be taken to prevent future occurrences;

� Ensure there is adequate capacity at the SRP and TGU. Redundant units can prevent flaring by allow-

Continued on page 4

October 2000 3

United StatesEnvironmental Protection AgencyOffice of Regulatory Enforcement(2248A)1200 Pennsylvania Avenue, NWWashington, DC 20460

Official BusinessPenalty for Private Use $300

‘Enforcement�Alert’ newsletter

Recycled/Recyclable. Printed with Soy/Canola Ink on paper that contains at least 30% recycled fiber


ing one unit to operate if the other needsto be shut down for maintenance or anupset; and

� Prepare an accurate estimateof the total SO

2 released (using clear

calculation procedures) for each acidgas flaring incident.

Identifying the root cause of the flar-ing incident gives the refinery the op-portunity to fix the problem before ithappens again. It also enables the facil-

ity to assess whether the flaring inci-dent was caused by a true malfunction,which is considered acceptable engi-neering practices.

A reference procedure for evaluat-ing if good air pollution practices arebeing used when future acid gas flar-ing events occur can be found in theConsent Decree, C.A. No. 3:97CV7790N.D. Ohio, entered May 5, 1999 (seehttp://www.epa.gov/oeca/ore/aed).

For more information, contactPatric McCoy at U.S. EPA’s Region 5office in Chicago at (312) 886-6869,

EPCRA Section 304 requires that unpermitted releases of extremely haz-ardous substances in excess of their reportable quantity be reported immedi-ately to the State Emergency Response Commission and Local EmergencyPlanning Committee.The flaring of hydrogen sulfide may require reporting ifmore than 500 pounds (the reportable quantity) of SO

2 are released within a

24-hour period. The Clean Air Act recognizes that accidents, malfunctions,start ups and shut downs may cause excess emissions even when the facil-ity has implemented reasonable measures to avoid them. However, it is stillimportant to alert emergency response personnel when these releases occur,as even short periods of flaring can emit large quantities of SO

2. For example,

a medium-sized refinery with an SRP that processes 500 tons of acid gaseach day could release as much as 40 tons of SO

2 at the flare in only one

hour, more than 150 times the reportable quantity.

EPCRA Reporting Requirements for Flaring Incidents

E-mail: [email protected]; andregarding federally permitted releasequestions, contact Ginny Phillips, Of-fice of Regulatory Enforcement,Toxics and Pesticides EnforcementDivision at (202) 564-6139,Email:[email protected].

Useful ComplianceAssistance Resources

CAA Applicability DeterminationIndex:http://www.epa.gov/oeca/eptdd/adi.html

Technology Transfer Networkhttp://www.epa.gov/ttn/

Office of Regulatory Enforcement:http://www.epa.gov/oeca/ore/

RCRA Online:http://www.epa.gov/rcraonline/

Compliance Assistance Centers:http://www.epa.gov/oeca/mfcac.html

Audit Policy Information:http://www.epa.gov/oeca/ore/apolguid.html

Small Business Gateway:http://www.epa.gov/smallbusiness/

EPA Enforcement:EPA Enforcement: National PetroleumNational Petroleum Refinery InitiativeRefinery Initiative

Petroleum Refinery InitiativePetroleum Refinery InitiativeFour Program Areas C Sources of Refinery Emissions

(“Marquee” Issues)

� New Source Review/Prevention of Significant Deterioration(NSR/PSD) � Fluidized Catalytic Cracking Units (FCCUs) � Heaters and Boilers

� New Source Performance Standards (NSPS) � Flares � Sulfur Recovery Units � Fuel Gas Combustion Devices (including heaters & boilers)

� Leak Detection and Repair (LDAR)

� Benzene

2Updated 03/21/06 - Subject to Revision

Refinery National StrategyRefinery National Strategy

� Goal: By the end of FY 05, coverage of 80% of domesticrefining capacity (by settlement for all “marquee” issues,filed civil action or referral to the Department of Justice)

� Goal: Address 90% of domestic refining capacity locatedin environment justice areas

� National Priority:

� Will file cases against those who do not settle

� Will level the playing field


Refinery National StrategyRefinery National Strategy� As of October 2005

� Approximately 77% of the nation’s refinery capacity is under lodged or entered “global” settlements (“global” settlements address marquee issues at refineries company-wide) � 17 refiners

� 85 refineries

� $4.4 billion in capital costs for new control technologies

� $63 million in civil penalties

� $60 million in environmental projects (such as the installation of additional controls and equipment to further reduce refinery emissions, emergency response equipment for local communities, and wildlife habitat restoration)

� Located in 25 states

� Emissions reductions from FCCUs, sulfur recovery units, heaters and boilers,flares: � 80,000 tpy NOx � 235,000 tpy SO2 (estimated annual reductions when all current settlements are fully implemented)


U.S. Petroleum RefineriesU.S. Petroleum Refineries


U.S. Petroleum RefineriesU.S. Petroleum RefineriesNational Crude Petroleum Refining Capacity

EPA Region Crude Refining Capacity under CD

Total Crude Refining Capacity

Percent of Capacity under CD

Region 1 No petroleum refineries are located in Region 1 Region 2 638,000 1,348,500 47 Region 3 958,300 1,035,000 93 Region 4 598,000 941,725 64 Region 5 2,103,200 2,321,450 91 Region 6 6,778,987 8,289,019 82 Region 7 182,200 292,200 62 Region 8 466,700 632,200 74 Region 9 1,897,300 2,092,300 91 Region 10 244,600 996,275 25 U.S. Total 13,867,287 17,948,669 77 Capacity data from Oil & Gas Journal’s 2005 Worldwide Refining Survey, December 19, 2005, except as noted on following Region slides.

Updated 03/21/06 - Subject to Revision 6

Region 2 Petroleum RefineriesRegion 2 Petroleum Refineries


Region 2 Petroleum RefineriesRegion 2 Petroleum RefineriesRefineries under CD Refineries not under CD

New Jersey New Jersey 3. Citgo Asphalt Refining Co. – Paulsboro 1. Amerada Hess – Port Reading –

– 84,000 62,500 (FCCU capacity) 4. ConocoPhillips – Bayway – 238,000 2. Chevron Corp. – Perth Amboy – 5. Sunoco Inc. – Eagle Point – 150,000 80,000 6. Valero Energy Corp. – Paulsboro – Puerto Rico

166,000 7. Shell Chemical Yabucoa Inc. – Yabucoa – 73,000

U.S. Virgin Islands 8. Hovensa LLC – St. Croix – 495,000

By state: Number on map, Company, Refinery, Crude oil capacity (barrels/day)Data from Oil & Gas Journal’s 2005 Worldwide Refining Survey, December 19, 2005, except:1. NPRA Refining Capacity Report 2005 2. January 2006 EIA Petroleum Profile for New Jersey 3. Citgo press release dated 11/28/2004




Region 3 Petroleum RefineriesRegion 3 Petroleum RefineriesRefineries under CD

Delaware 9. Valero Energy Corp.– Delaware City

190,000 Pennsylvania 11. ConocoPhillips – Trainer – 185,000 12. Sunoco Inc.– Marcus Hook – 175,000 13. Sunoco Inc. – Philadelphia – 330,000 Virginia 15. Giant Refining Company – Yorktown –

58,900 West Virginia 16. Ergon-West Virginia, Inc. – Newell –

19,400

Refineries not under CD Pennsylvania 10. American Refining Group –

Bradford – 10,000 14. United Refining Co. – Warren –

66,700

By state: Number on map, Company, Refinery, Crude oil capacity (barrels/day) Data from Oil & Gas Journal’s 2005 Worldwide Refining Survey, December 19, 2005





Georgia 20. Citgo Asphalt Refining Co. –

Savannah – 28,000 Kentucky 21. Marathon Petroleum Company LLC

– Catlettsburg – 222,000 Mississippi 23. Chevron Corp. – Pascagoula –

325,000 24. Ergon Refining Inc. – Vicksburg –

23,000

Refineries not under CD Alabama 17. Hunt Refining Company –

Tuscaloosa – 43,225 18. Shell Chemical Company – Saraland

– 85,000 19. Trigeant Petroleum – Mobile Bay –

20,000 Kentucky 22. Somerset Refinery Inc. – Somerset

– 5,500 Tennessee 25. Valero Energy Corp. – Memphis –

190,000

By state: Number on map, Company, Refinery, Crude oil capacity (barrels/day)Data from Oil & Gas Journal’s 2005 Worldwide Refining Survey, December 19, 2005, except:20. Citgo press release dated 11/28/2004





Illinois 26. Citgo Petroleum Corp. – Lemont – 158,650 27, 28. ConocoPhillips – Wood River and Distilling

West – 306,000 29. ExxonMobil Refining and Supply Co. – Joliet –

238,000 30. Marathon Petroleum Company LLC – Robinson –

192,000 Indiana 31. BP PLC – Whiting – 399,000 Michigan 33. Marathon Petroleum Company LLC – Detroit –

100,000 Minnesota 34. Flint Hills Resources – Pine Bend – 279,300 35. Marathon Petroleum Company LLC – St. Paul

Park – 70,000 Ohio 36. BP PLC – Toldeo – 147,250 37. Marathon Petroleum Company LLC – Canton –

73,000 38. Sunoco Inc. – Toledo – 140,000

Refineries not under CD Indiana 32. Countrymark Cooperative Inc. – Mount Vernon –

23,500 Ohio 39. Valero Energy Corp. – Lima – 161,500 Wisconsin 40. Murphy Oil USA Inc. – Superior – 33,250

By state: Number on map, Company, Refinery, Crude oil capacity (barrels/day)Data from Oil & Gas Journal’s 2005 Worldwide Refining Survey, December 19, 2005





Arkansas 42. Lion Oil Company – El Dorado – 70,000 Louisiana 47. Citgo Petroleum Corp. – Lake Charles – 440,000 48. ConocoPhillips – Alliance – 247,000 49. ConocoPhillips – Lake Charles – 239,000 50. ExxonMobil Refining and Supply Co. – Baton

Rouge – 501,000 51. ExxonMobil Refining and Supply Co. – Chalmette

– 188,000 52. Marathon Petroleum Company LLC – Garyville –

245,000 53. Motiva Enterprises LLC – Convent – 235,000 54. Motiva Enterprises LLC – Norco – 220,000 58. Valero Energy Corp. – Krotz Springs – 83,100 59. Valero Energy Corp. – St. Charles – 186,000 New Mexico 60. Giant Refining Company – Ciniza – 26,000 61. Giant Refining Company – Bloomfield – 18,600 62, 63. Navajo Refining Company – Artesia and

Lovington – 60,000 Oklahoma 64. ConocoPhillips – Ponca City – 187,000 66. Sunoco Inc. – Tulsa – 85,000 67. Valero Energy Corp. – Armore – 87,877

Texas 71. BP PLC – Texas City – 446,500 72, 73. Citgo Petroleum Corp. – Corpus Christi East

and West Plants – 156,750 74. ConocoPhillips – Borger – 146,000 75. ConocoPhillips – Sweeny – 247,000 76. ExxonMobil Refining and Supply Co. – Baytown –

563,000 77. ExxonMobil Refining and Supply Co. – Beaumont

– 348,500 78, 79. Flint Hills Resources – Corpus Christi East

and West Plants – 279,300 82. Marathon Petroleum Company LLC – Texas City

– 72,000 83. Motiva Enterprises LLC – Port Arthur – 285,000 85. Shell Deer Park Refining Co. – 333,700 87, 88. Valero Energy Corp. – Corpus Christi East

and West Plants – 205,000 89. Valero Energy Corp. – Houston – 90,000 90. Valero Energy Corp. – McKee – 166,660 92. Valero Energy Corp. – Texas City – 225,000 93. Valero Energy Corp. – Three Rivers – 96,000


Region 6 Petroleum RefineriesRegion 6 Petroleum RefineriesRefineries not under CD

Arkansas 41. Cross Oil and Refining Company –

Smackover – 7,000 Louisiana 43. Calcasieu Refining Co. – Lake Charles –

15,680 44. Calumet Lubricants Co. – Cotton Valley –

9,500 45. Calumet Lubricants Co. – Princeton –

9,500 46. Calumet Lubricants Co. – Shreveport

35,000 55. Murphy Oil USA Inc. – Meraux – 125,000 56. Placid Refining Co. LLC – Port Allen –

55,000 57. Shell Chemical Company – St. Rose –

55,000 Oklahoma 65. Sinclair Oil Corp. – Tulsa – 50,000 68. Wynnewood Refining Co. – Wynnewood –

52,500

Texas 69. AGE Refining And Manufacturing – San

Antonion – 12,000 70. Alon USA – Big Spring – 70,000 80. LaGloria Oil and Gas Co. – Tyler – 60,000 81. Lyondell-Citgo Refining LP – Houston –

282,600 84. Pasadena Refining System – 100,000 86. Total SA – Port Arthur – 231,252 91. Valero Energy Corp. – Port Arthur –

250,000 94. Western Refining Inc. – El Paso – 90,000





Region 7 Petroleum RefineriesRegion 7 Petroleum RefineriesRefineries under global CD Refineries not under CD

None Kansas 96. Frontier – El Dorado – 110,000

Refineries under non-global CD Kansas 95. Coffeyville Resources Refining &

Marketing – Coffeyville – 100,000 97. National Cooperative Refining

Association – McPherson – 82,200 Note: Coffeyville Resources Refining & Marketing and National Cooperative Refining Association are both under consent decrees with the United States and the State of Kansas that cover some, but not all, of the marquee issues of the National Petroleum Refinery Initiative.






Colorado 98. Suncor Energy Products – Denver West

Plant – 92,000 99. Suncor Energy Products – Denver East

Plant – 28,000 Montana 100. Cenex Harvest States – Laurel – 57,500 101. ConocoPhillips – Billings – 58,000 102. ExxonMobil Refining and Supply Co. –

Billings – 60,000 103. Montana Refining Company – Great Falls

– 8,200 North Dakota 104. Tesoro West Coast Co. – Mandan –

58,000 Utah 106. Chevron Corp. – Salt Lake City – 45,000 109. Tesoro West Coast Co. – Salt Lake City

60,000

Refineries not under CD Utah 104. Big West Oil LLC – Salt Lake City –

25,000 107. Holly Corporation – Woods Cross –

25,000 108. Silver Eagle Refining Inc. – Woods Cross

– 12,500 Wyoming 110. Frontier Refining Inc. – Cheyenne –

46,000 111. Sinclair Oil Corp. – Sinclair – 22,000 112. Sinclair/Little America – Casper – 22,500 113. Wyoming Refining Co. – Newcastle –

12,500






California 114. Big West Oil LLC – Bakersfield – 65,000 115. BP PLC – Carson – 247,000 116. Chevron Corp. – El Segudo – 260,000 117. Chevron Corp. – Richmond – 225,000 118, 119. ConocoPhillips – LAR-Carson and

Wilmington – 138,700 120, 121. ConocoPhillips – SF-Rodeo and

Santa Maria – 120,000 122. ExxonMobil Refining and Supply Co. –

Torrance – 149,500 126. Shell Oil Products US – Los Angeles

100,000 127. Shell Oil Products US – Martinez –

157,600 128. Tesoro Corp. – Golden Eagle – 161,000 129. Valero Energy Corp. – Benicia – 139,500 130. Valero Energy Corp. – Wilmington –

80,000 Hawaii 131. Chevron Corp. – Hawaii – 54,000

Refineries not under CD California 123. Kern Oil and Refining Co. – Bakersfield –

25,000 124. Paramount Petroleum Corp. – Long

Beach – 52,000 125. San Joaquin Refining Co., Inc. –

Bakersfield – 24,300 Hawaii 132. Tesoro Hawaii Corp. – Hawaii – 93,700






Washington 139. BP PLC – Cherry Point – 220,400 140. ConocoPhillips – Ferndale – 96,000 141. Shell Oil Products US – Puget

Sound – 306,000


Refineries not under CD Alaska 133. BP PLC – Kuparuk – 14,500 134. BP PLC – Prudhoe Bay – 15,000 135. Flint Hills Resources – North Pole –

215,175 136. Petro Star Inc. – North Pole –

17,500 137. Petro Star Inc. – Valdez – 48,000 138. Tesoro Alaska Company – Kenai –

72,000 Washington 142. Tesoro West Coast Co. – Anacortes

– 113,300 143. US Oil and Refining Co. – Tacoma –

35,800


Petroleum Refinery InitiativePetroleum Refinery Initiative

Actual Emissions Reductions from Settling Refiners under Consent Decrees

(Entered as of June 1, 2005)


FCC

U E

mis

sion

s (to

ns/y

ear)

Actual FCCU Emissions from Refineries under Consent Decrees

(Koch, BP, Motiva-Equilon-Deer Park, MAP, Conoco, Montana, Lion, Coastal, CHS) 200,000

PM

CO 180,000 NOx

SO2

160,000

140,000

120,000

100,000

80,000

60,000

40,000

20,000

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Actual FCCU SO2 Emissions from Refineries under Consent Decrees


90,000

80,000

70,000

60,000

50,000

40,000

30,000

20,000

10,000

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006


FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Actual FCCU NOx Emissions from Refineries under Consent Decrees


20,000

15,000

10,000

5,000

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006


Reductions in SO2 from FlaringReductions in SO2 from Flaring( Koch, BP,( Koch, BP, MotivaMotiva--EquilonEquilon--DeerDeer Park, MAP, andPark, MAP, and ConocoConoco Consent Decrees)Consent Decrees)

1200

1000

800

600

400

200

0 2 Years Prior to DOE 1 Year Prior to DOE 1 Year After DOE 2 Years After DOE 3 Years After DOE

Years Pre- and Post- Date of CD Entry

Tons

SO

2 R

elea

sed

from

Aci

d G

as F

larin

g



Schedule for Installation of Controls:All Refiners

(Decrees entered as of June 1, 2005)


Fluidized Catalytic Cracking Unit (FCCU) Emissions Reduction Compliance Dates2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Flint Hills DOL Dec 2000

FCCU SO2

FCCU NOX

2�

S

�

S S S

BP DOL Jan 2001

FCCU SO2

FCCU NOX

� � � 3� 1

3S2

4�

S 2S S

M-E-DP DOL Mar 2001

FCCU SO2

FCCU NOX

2� � � S

S

�

2S

� 2�

S S S 2S

�

MAP DOL May 2001

FCCU SO2

FCCU NOX

2� � �

S

� � 2�

4S S S S

Conoco DOL Dec 2001

FCCU SO2

FCCU NOX

� � �

2S3

2� 4

S5 S S S

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1BP Carson, Texas City FCCU 1, Texas City FCCU 2: Compliance date for SO2 final limits is date of entry of Fourth Amendment to the Consent Decree, October 7, 2005.2BP Carson, Texas City FCCU 1, Whiting FCU 600: Compliance date for NOx final limits is date of entry of Fourth Amendment to the Consent Decree, October 7, 2005.3Ponca City 5: NOx reducing additive demonstration report provides interim NOx limits until the hardware limits are effective.4Suncor Denver: SO2 reducing additive demonstration report deadline based on SO2 demonstration beginning 9/2005.5Suncor Denver: NOx reducing additive demonstration report deadline based on NOx demonstration beginning 6/2005.


FCCU Emissions Reduction Compliance Dates2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Montana DOL Dec 2001

FCCU SO2

FCCU NOX

�

S

Navajo DOL Dec 2001

FCCU SO2

FCCU NOX

�

S

Lion Oil DOL Mar 2003

FCCU SO2

FCCU NOX

�

S

Chevron DOL Oct 2003

FCCU SO2

FCCU NOX

�

S

� � � � 1

S S S

�

S

DOL Oct 2003

FCCU SO2

FCCU NOX

Sunoco (Coastal)

�

U S

CHS DOL Oct 2003

FCCU SO2

FCCU NOX

� 2

S

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1Chevron Salt Lake City: If WGS is installed, compliance date is 3/2012; if WGS is not installed, compliance date is 9/2010.2CHS Laurel: If WGS is installed, compliance date is 12/2009; if WGS is not installed, compliance date is 12/2007.


FCCU Emissions Reduction Compliance Dates2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

CITGO DOL Oct 2004

FCCU SO2

FCCU NOX U

� 2�

S

�

2S

�

S

�

S S

DOL Jan 2005

FCCU SO2

FCCU NOX

Conoco-Phillips

2� 2� 2� � �

3S S

� �

S

� �

S 2S S S

�

S1 2S

Sunoco DOL Jun 2005

FCCU SO2

FCCU NOX

�

S

�

S

�

S

Valero DOL Jun 2005

FCCU SO2

FCCU NOX

� � � 2� 2 �

2S S

� �

S 2S

� � 4� 3 � �

DOL Oct 2005

FCCU SO2

FCCU NOX

ExxonMobil &Chalmette

� 3� 4

�

S 2U S5

S S

�

S6

�

S 2S

�

S

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes: 1ConocoPhillips Alliance: If SNERT is installed, compliance date is 3/2015; if SNERT is not installed, compliance date is 12/2009. 2Valero Paulsboro, Texas City: Compliance dates for WGS and SO2 final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of the second quarter 2006. 3Valero Corpus Christi East, Denver, Wilmington: One refinery must install WGS to meet hard limits in 2010 while the other refineries must use SO2 reducing additives. A non-selected refinery can take hard limits in lieu of using additives. 4ExxonMobil Torrance, Beaumont, Baytown FCCU 3: Compliance dates for SO2 final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of 2006. 5ExxonMobil Torrance, Baton Rouge: Compliance dates for NOx final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of 2006. 6Chalmette: If additives are found to be effective, compliance date is 6/30/2007, if additives are not effective, compliance date is 12/31/2008.



Information and Emissions Data by

Individual Refiner/Refinery


Flint Hills (formerly Koch)Flint Hills (formerly Koch)December 2000December 2000

� 3 refineries in Texas and Minnesota � $80 million in injunctive relief � Annual Reductions � 5,200 tons of NOx and SO2

� Penalty: $1 million � SEPs: $3.5 million � Co-Plaintiff: Minnesota � The refining business of Koch Petroleum Group was

restructured into Flint Hills Resources in 2002


Koch FCCU Emissions Reduction Compliance DatesDOL Dec 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Flint Hills Corpus Christi East FCCU SO2

FCCU NOX

�

U S U S Flint Hills Corpus Christi West

FCCU SO2

FCCU NOX U

�

S U S U S Flint Hills Pine Bend

FCCU SO2

FCCU NOX

�

U S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:Hardware is not required if the use of NOx reducing additives lower emissions to meet a specific limit.


Koch Emissions Controls Milestones

Eliminate Fuel Oil Burning in Heaters

and Boilers Corpus Christi East

SNCR Installed Pine Bend FCCU

NOx Burners on all

SO2 Limit: 25/50 ppm greater than 40 Pine Bend FCCU

and West Install Current or Next Generation Ultra Low-

mmBTU/hr

Heaters and Boilers

NESHAP

Canisters for Benzene WasteDate of

Lodging

CD Expected to be Completed

Q2 2009

Install Carbon

2000 2001 2002 2003 2004 2005 2006 2007

Flare Gas Legend Recovery FCCU Completed FCCU Upcoming

System Installed Milestones Milestones Corpus Christi

East Heaters and Boilers Heaters and Boilers Completed Milestones Upcoming Milestones

Benzene Waste NESHAP Completed Milestones

Flaring System Completed Milestones


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Koch Actual FCCU SO2 Emissions Date of Lodging: 12/22/2000

2,500

2,000

1,500

1,000

500

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Pine Bend

Corpus Christi West

Corpus Christi East

- Corpus Christi East scrubber optimization begins - Corpus Christi West scrubber optimization begins

- Pine Bend additives and hard limits (Dec)


Koch Actual FCCU NOx EmissionsDate of Lodging: 12/22/2000

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

500

1,000

1,500

2,000

2,500

3,000

FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Pine Bend

Corpus Christi West

Corpus Christi East

Future Activities - Corpus Christi East will implement SNCR plus additive (Dec 2005)

- Corpus Christi West begin trials and SNCR evaluations (May)

- Pine Bend implemented SNCR plus additive (Dec)


BPBPJanuary 2001January 2001

� 8 refineries in California, Indiana, North Dakota, Texas, Utah, Virginia, Washington and Ohio

� $600 million in injunctive relief � Annual Reductions

� 22,000 tons of NOx � 27,300 tons of SO2

� Penalty: $10 million � Co-Plaintiffs: Indiana, Ohio and Northwest Air Pollution Authority � Tesoro Petroleum Corporation acquired the Mandan, North Dakota and

Salt Lake City, Utah refineries in 2001 � Giant Yorktown, Inc. acquired the Yorktown, Virginia refinery in 2002


BP FCCU Emissions Reduction Compliance DatesDOL Jan 2001 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Carson FCCU SO2

FCCU NOX

� 1

S2

Texas City 1 FCCU SO2

FCCU NOX

� 1

S2

Texas City 2 FCCU SO2

FCCU NOX

� 1

S Texas City 3

FCCU SO2

FCCU NOX

�

S Toledo

FCCU SO2

FCCU NOX U

�

S Whiting 500

FCCU SO2

FCCU NOX

�

S Whiting 600

FCCU SO2

FCCU NOX S2

�

Tesoro Mandan FCCU SO2 � �

Tesoro Salt Lake CityFCCU SO2 �

Giant Yorktown FCCU SO2 � �

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1BP Carson, Texas City FCCU 1, Texas City FCCU 2: Compliance date for SO2 final limits is date of entry of Fourth Amendment to the Consent Decree, October 7, 2005.2BP Carson, Texas City FCCU 1, Whiting FCU 600: Compliance date for NOx final limits is date of entry of Fourth Amendment to the Consent Decree, October 7, 2005.


BP Emissions Controls MilestonesNOx Limit

Texas City FCCU 2: 20/40 ppmWhiting FCCU 500: 40/80 ppm

SO2 Limit Texas City FCCU 3: 25/50 ppm

Toledo FCCU: 160/260 ppmWhiting FCCU 500: 25/50 ppmWhiting FCCU 600: 50/125 ppm

CO Limit Texas City FCCU 2: 500 ppm Whiting FCCU 500: 500 ppm

NOx Limit Carson FCCU: 20/60 ppm

Texas City FCCU 1: 40/80 ppmWhiting FCCU 600: 20/40 ppm

SO2 Limit Carson FCCU: 50/150 ppm

Texas City FCCU 1: 50/150 ppmTexas City FCCU 2: 126/250 ppm

SO2 Limit: 9.8 kg SO2/1,000 kg cokeburn

Whiting FCCU 600: 500 ppm Carson FCCU: 500 ppm

2001 2002 2003 2004 2005 2006 2007 2008

WGS Installed Tesoro Mandan FCCU

CO Limit: 500 ppm Texas City FCCU 3

CO Limit: NSPS Subparts A and J Tesoro Salt Lake City FCCU

Texas City FCCU 1

Controls Installed on 66% of Heater and Boiler Heat Input Capacity

CO Limit: 500 ppm Tesoro Mandan FCCU

Toledo FCCU Giant Yorktown FCCU

Eliminate Fuel Oil Burning in Heaters and

Boilers Tesoro Mandan

Eliminate Fuel Oil

Burning in Heaters

and Boilers Giant

Yorktown


and Boilers Tesoro Salt Lake City


and Boilers Whiting

PM Limit: 1.0 lb PM/ 1,000 lbs coke burned Giant Yorktown FCCU

PM Limit: 1.0 lb PM/ 1,000 lb coke burned

Toledo FCCU

Date of Lodging

CD Expexted to be Completed in

Q4 2012

Legend

Heaters and Boilers Completed Milestones

FCCU Completed Milestones

FCCU Upcoming Milestones

Tesoro Salt Lake City FCCU CO Limit


BP Actual FCCU SO2 EmissionsDate of Lodging: 1/18/2001

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

5,000

10,000

15,000

20,000

25,000

FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Yorktown Salt Lake City Mandan Whiting 600 Whiting 500 Toledo Texas City 3 Texas City 2 Texas City 1 Carson

- Texas City 1 Hydrotreater optimization (June) - Texas City 3 additives trials (June) - Toledo additive trials (June) - Carson additive trials (July) - Salt Lake City hard limit (Aug) - Texas City 2 additive trials (Dec) - Yorktown additive trials (Dec)

- Whiting 500 additive trial (Jan)


FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

BP Actual FCCU NOx Emissions

Date of Lodging: 1/18/2001

5,000

Yorktown Salt Lake City

4,500 MandanWhiting 600Whiting 500Toledo4,000 Texas City 3Texas City 2Texas City 1

3,500 Carson

3,000

2,500

2,000

1,500

1,000

500

0

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

- Texas City 1 additive trial (May) - Toledo SNCR to be installed (June) - Whiting 600 SCR installed (June)

- Whiting 500 additive trial (Aug)

- Carson additive trial (Jan) - Texas City 3 additive trial (June)


MotivaMotiva--EquilonEquilon--DeerDeer ParParkMarch 2001March 2001

� 9 refineries in California, Washington, Louisiana, Delaware and Texas � $400 million in injunctive relief � Annual Reductions


� Penalty: $9.5 million � SEPs: $5.5 million � Co-Plaintiffs: Delaware, Louisiana, Northwest Air Pollution Authority and

Sierra Club � Premcor Refining Group, Inc. acquired the Delaware City refinery in 2004 � Valero acquired Premcor and the Delaware City refinery in 2005 � Big West of California, LLC acquired the Bakersfield refinery in 2005


M-E-DP FCCU Emissions Reduction Compliance DatesDOL Mar 2001 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Motiva Convent FCCU SO2

FCCU NOX U

��

S Motiva Norco

FCCU SO2

FCCU NOX

�

U S Motiva Port Arthur

FCCU SO2

FCCU NOX

�

U S Shell Deer Park

FCCU SO2

FCCU NOX

��

US Shell Los Angeles

FCCU SO2

FCCU NOX

�

U

�

S Shell Martinez

FCCU SO2

FCCU NOX

�

U

�

S Shell Puget Sound

FCCU SO2

FCCU NOX U

��

S Valero Deleware City FCCU

FCCU SO2

FCCU NOX U

�

S

�

Valero Deleware City Coker FCCU SO2

FCCU NOX U

� �

S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits).


M-E-DP Emissions Controls Milestones

Regenerative WGS Installed

Valero Delaware City FCU

2001 2002 2003 2004 2005 2006 2007 2008

66% NOx Reductions

from Heaters and Boilers

WGS Installed Convent FCCU Puget FCCU

Regenerative WGS Installed Valero Delaware City FCCU

SNCR Installed Norco FCCU

SCR Installed Deer Park FCCU

Install Carbon Canisters for

Benzene Waste NESHAP

Final NOx Reductions



Boilers Convent Norco

Port Arthur

SNCR Installed Valero Delaware

City FCU

Eliminate Fuel Oil Burning in

SO2 Limit: 25/50 ppm

Norco FCCU Port Arthur FCCU


Boilers Valero

Delaware City Legend

Date of Lodging


Sulfur Recovery Plants subject to NSPS subparts A

and J

Heaters and Boilers

Deer Park

Sulfur Recovery Plant Completed Milestones



Heaters and Boilers Upcoming Milestones




FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Motiva-Equilon-Deer Park Actual FCCU SO2 Emissions


60,000 Delaware City (Coker) Delaware City (FCCU) Puget Sound Martinez Los Angeles

50,000

- Norco scrubber installed (June) - Port Arthur scrubber installed (June)

Deer Park Port Arthur Norco Convent

40,000

30,000

Future Events - Delaware City Coker

20,000 scrubber to be installed (June 2006) - Delaware City FCCU scrubber to be installed (Dec 2006) - Convent scrubber to be 10,000 installed (Dec 2006) -Puget Sound scrubber to be installed (Dec 2006)

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

- Martinez additive trials (Feb) - Los Angeles additive trials (Mar)

- Deer Park scrubber installed (Dec)

- Convent additive trial (June)


FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Motiva-Equilon-Deer Park Actual FCCU NOx Emissions


8,000 Delaware City (Coker) Delaware City (FCCU) Puget Sound

7,000 Martinez Los Angeles Deer Park Port Arthur

6,000 Norco Convent

5,000

4,000

3,000

Future Events 2,000 - Martinez SNCR optimization

complete (June 2005) - Delaware City Coker NOx control hardware to be installed (Nov 2005) 1,000

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

- Port Arthur additive trial (Feb) - Los Angeles

- Convent additive trial (June) - Norco SNCR - Puget Sound CO installation (Dec) - Delaware City FCCU CO Boiler Optimization (Dec) - Deer Park SCR installed (Dec)

(Dec)

additive trial (Aug)

Boiler optimization


Marathon Ashland PetroleumMarathon Ashland PetroleumMay 2001May 2001

� 7 refineries in Texas, Louisiana, Kentucky, Illinois,Ohio, Minnesota and Michigan

� $265 million in injunctive relief � Annual Reductions � 8,000 tons of NOx � 12,800 tons of SO2

� Penalty: $3.8 million � SEPs: $6.5 million � Co-Plaintiffs: County of Wayne, Michigan, Louisiana

and Minnesota


MAP FCCU Emissions Reduction Compliance DatesDOL May 2001 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Canton FCCU SO2

FCCU NOX U

�

S Catlettsburg FCCU

FCCU SO2

FCCU NOX

�

S Catlettsburg RCCU

FCCU SO2

FCCU NOX

�

U S Detroit

FCCU SO2

FCCU NOX U

�

S Garyville

FCCU SO2

FCCU NOX

�

U S Robinson

FCCU SO2

FCCU NOX

�

U S St. Paul Park

FCCU SO2

FCCU NOX U

�

S Texas City

FCCU SO2

FCCU NOX

� �



MAP Emissions Controls Milestones

Shutdown Catlettsburg FCCU 1

PM Limit: 0.9 lbs PM/ 1,000 lb coke burned

Canton FCCU PM Limit: 1.0 lb PM/ 1,000 lb coke burned Catlettsburg FCCU 1

Catlettsburg FCCU 109

SO2 Limit: 25/50 ppm Catlettsburg FCCU 109

Legend FCCU Completed

Milestones FCCU Upcoming

Milestones



PM Limit: 0.9 lb PM/1,000 lb coke

burned St. Paul Park

FCCU


Q2 2011


burnedDetroit FCCU

SO2 Limit: 20 ppm Texas City FCCU

SO2 Limits: 50/ 100 ppm

Canton FCCUWGS Installed Texas City FCCU

PM Limit: 1 lb PM/ 1,000 lb coke burned

Texas City FCCU

SO2 Limit: 25/50 ppm Robinson FCCU Garyville FCCU


Robinson FCCU Garyville FCCU

SO2 Limit Detroit FCCU: 35/70 ppm

St. Paul Park FCCU: 50/100 ppm Date of Lodging

2001 2002 2003 2004 2005 2006 2007 2008

Eliminate Fuel 66% NOx Final NOx Oil Burning in Reductions Reductions Heaters and from Heaters from Heaters

Boilers and Boilers and Boilers


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

MAP Actual FCCU SO2 EmissionsDate of Lodging: 5/11/2001

16,000

14,000

12,000

10,000

8,000

6,000

4,000

2,000

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Texas City St. Paul Park Robinson Garyville Detroit Catlettsburg RCCU Catlettsburg FCCU Canton

Robinson WGS installed (Nov)

Detroit began catalyst additive program

- Texas City WGS installed (Mar) - Canton and St. Paul Park began catalyst additive program

- Catlettsburg FCCU shut down (Jan) - Catlettsburg RCCU revamp and began catalyst additive program (May)


FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

MAP Actual FCCU NOx EmissionsDate of Lodging: 5/11/2001

5,000

4,500

4,000

3,500

3,000

2,500

2,000

1,500

1,000

500

0

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Texas City St. Paul Park Robinson Garyville Detroit Catlettsburg RCCU Catlettsburg FCCU Canton

Garyville began catalyst additive program

Canton, Detroit, St. Paul Park began catalyst additive programs

- Catlettsburg FCCU shut down (Jan) - Catlettsburg RCCU revamp and began catalyst additive (May)


ConocoConoco(pre(pre--merger with Phillips Petroleum)merger with Phillips Petroleum)

December 2001December 2001

� 4 refineries in Louisiana, Oklahoma, Montana and Colorado � $110 million in injunctive relief � Annual Reductions

� 3,210 tons of NOx� 4,000 tons of SO2

� Penalty: $1.5 million � SEPs: $5.1 million � Co-Plaintiffs: Colorado, Lousiana, Oklahoma and Montana� Suncor Energy (U.S.A.) Inc. acquired the Denver, Colorado

refinery in 2003 (later integrated with adjacent refinery acquired from Valero in 2005)


Conoco FCCU Emissions Reduction Compliance DatesDOL Dec 2001 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Billings FCCU SO2

FCCU NOX

�

U

�

S Lake Charles

FCCU SO2

FCCU NOX

�

U

�

S Ponca City 4

FCCU SO2

FCCU NOX

�

U

�

S Ponca City 5

FCCU SO2

FCCU NOX

�

U

�

S1 U S Suncor Denver

FCCU SO2

FCCU NOX

�

U

� 2

S3

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1Ponca City 5: NOx reducing additive demonstration report provides interim NOx limits until the hardware limits are effective.2Suncor Denver: SO2 reducing additive demonstration report deadline based on SO2 demonstration beginning 9/2005.3Suncor Denver: NOx reducing additive demonstration report deadline based on NOx demonstration beginning 6/2005.


Conoco Emissions Controls Milestones

2001 2002 2003 2004 2005 2006 2007 2008

SNCR Installed Ponca City FCCU 5


Ponca City FCCU 5

Sulfur Recovery Plants Subject to NSPS Subparts A

and J Billings

Lake Charles Ponca City



PM Limit: 1.0 lb PM/1,000 lb coke burned

Suncor Denver FCCU

Install Series Carbon Canisters for Benzene

Waste NESHAP Billings

Ponca City Suncor Denver

PM Limit: 1.0 lb PM/1,000 lb coke burned

Lake Charles FCCU FCCU CO Limit: 500 ppm

FCCU CO Limit: 100 ppm

Sulfur Recovery Plants Subject to NSPS Subparts A

and J Suncor Denver


burned Billings FCCU

PM Limit: 1.0 lb PM/1,000 lb coke burned Ponca City

FCCU 4

Flare Gas Recovery System Installed

Lake Charles

66% NOx Reductions


Date of Lodging

2009




Milestones


Sulfur Recovery Plant Upcoming Milestones


Benzene Waste NESHAP Upcoming Milestones



Flaring System Completed Controls


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Conoco and Suncor Actual FCCU SO2 Emissions


4000

3500

3000

2500

2000

1500

1000

500

0

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Denver

Ponca City 5

Ponca City 4

Lake Charles

Billings

- Ponca City 4 additive trail starts (May) - Ponca City 5 additive trail starts (Sept) - Lake Charles additive trail starts (Sept)

- Denver additive trial starts (May) - Billings additive trial starts (June)

Future Events - Billings hard limit (Dec 2005) - Ponca City 5 hard limit (Dec 2006) - Ponca City 4 hard limit (Dec 2008)


Conoco and Suncor Actual FCCU NOx Emissions Date of Lodging: 12/20/2001

Denver

Ponca City5

Ponca City4

Lake Charles

Billings

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 0

500

1000

1500

2000

2500

FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Future Events - Ponca City 5 SNCR to be installed (Dec 2006)

- Ponca City 4 additive trial starts (Oct)

- Lake Charles additive trial starts (Mar) - Ponca City 5 additive trial starts (May) - Denver additive trial starts (Jul) - Billings additive trial starts (Dec)


NavajoNavajo--MontanMontanaDecember 2001December 2001

� 3 refineries in New Mexico and Montana � $15 million in injunctive relief � Annual Reductions � 2,500 tons of NOx � 2,350 tons of SO2

� Penalty: $750,000 � SEPs: $200,000 � Co-Plaintiffs: New Mexico and Montana


Navajo-Montana FCCU Emissions Reduction Compliance DatesDOL Dec 2001 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Navajo Artesia FCCU SO2

FCCU NOX

��

U S Montana Great Falls

FCCU SO2

FCCU NOX

�

U

�



Navajo-Montana Emissions Controls Milestones


Navajo-Montana Actual FCCU SO2 EmissionsDate of Lodging: 1 2/20/2001

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

200

400

600

800

1,000

1,200

1,400

1,600

1,800

2,000

FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Artesia Great Falls

-Artesia scrubber installed (Oct)

- Great Falls additive trial starts (Jan)


Navajo-Montana Actual FCCU NOx EmissionsDate of Lodging: 12/20/2001

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

20

40

60

80

100

120

140

160

180

200

FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Great Falls

Artesia

- Great Falls additive trial starts (Feb) - Artesia additive trial starts (Mar)


Lion OilLion OilMay 2003May 2003

� 1 refinery in Arkansas � $21.5 million in injunctive relief � Annual Reductions � 530 tons of NOx � 650 tons of SO2

� Penalty: $348,000 � SEPs: $450,000 � Co-Plaintiffs: Arkansas


Lion Oil FCCU Emissions Reduction Compliance DatesDOL Mar 2003 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

El Dorado FCCU SO2

FCCU NOX

��

U S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits).


Lion Oil Emissions Controls Milestones

WGS Installed and SO2 Limits: 25/50 ppm El Dorado FCCU

PM Limit: 0.5 lbs PM/ 1,000 lbs coke burned

El Dorado FCCU CO Limits: 100/500 ppm LoTox Installed CD Expected to

El Dorado FCCU El Dorado FCCU be Completed



Sulfur Recovery Plant subject to NSPS subpart J

Eliminate Fuel Oil Burning from

Heaters and Boilers

Date of Lodging

2002 2003 2004 2005 2006 2007 2008 2009

Legend FCCU Completed FCCU Upcoming

Milestones Milestones

Heaters and Boilers Heaters and Boilers Completed Milestones Upcoming Milestones



LionActual FCCU SO2 EmissionsDate of Lodging: 3/11/2003

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

100

200

300

400

500

600

700

800

FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

El Dorado

- El Dorado scrubber installed (Apr)


Lion Actual FCCU NOx EmissionsDate of Lodging: 3/11/2003

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

20

40

60

80

100

120

140

160

180

200

FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

El Dorado


CHSCHS--CoastalCoastal--ErgoErgonOctober 2003October 2003

� 4 refineries in Mississippi, Montana, New Jersey and WestVirginia

� Annual Reductions � 1,100 tons of NOx � 2,800 tons of SO2

� Penalty: $2.9 million � SEPs: $1.6 million � Co-Plaintiffs: Montana (CHS), New Jersey (Coastal),

Mississippi Commission on Environmental Quality and WestVirginia Department of Environmental Protection (Ergon)

� Sunoco, Inc. acquired the Eagle Point (Westville, New Jersey)refinery in 2004


CHS FCCU Emissions Reduction Compliance DatesDOL Oct 2003 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Laurel FCCU SO2

FCCU NOX U

� 1

S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1Laurel: If WGS is necessary to meet the hard limit, the limit will become effective 12/2009.


CHS Emissions Controls Milestones

2003 2004 2005 2006 2007 2008

Final NOx Reductions from

Heaters and Boilers

PM Control Technology Installed

Laurel FCCU

Eliminate Fuel Oil Burning from

Tail Gas Treating Unit Installed Laurel Sulfur

Recovery Plant

SO2 Limit: 25/50 ppm

Laurel FCCUCO Limit: 500 ppm

Laurel FCCU

CO Limit: 150 ppm Laurel FCCU

66% NOx Reductions from

Heaters and Boilers

Date of Lodging

2009 2010 2011


Legend






Heaters and Boilers


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

CHS Actual FCCU SO2 Emissions

Date of Lodging: 9 /30/2003

900

800

700

600

500

400

300

200

100

0

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Laurel

Future Events -Laurel hard limit (Dec 2007)


FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

CHSActual FCCU NOx Emissions

Date of Lodging: 9 /30/2003

180

Laurel

160

140

120

100

80

60

40

20

0

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

-Laurel additive trial starts (Dec)


CEPOC FCCU Emissions Reduction Compliance DatesDOL Oct 2003 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Sunoco Eagle Point FCCU SO2

FCCU NOX

�

U U S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits).


CEPOC Emissions Controls Milestones

2003 2004 2005 2006 2007 2008


Heaters and Boilers

NOx Interim Limit: 75 ppm Sunoco Eagle Point FCCU

SO2 Limit: 25/50 ppm Sunoco Eagle Point FCCU

PM Limit: 0.5 lbs PM/1,000 lbs coke burned

Sunoco Eagle Point FCCU CO Limit: 100 ppm

Sunoco Eagle Point FCCU

Sulfur Recovery Plant Subject to NSPS Subpart J

NOx Control Technology

Installed Sunoco Eagle

Point

2009 2010


Date of Lodging



Milestones






and Boilers


FCC

U S

O2

Emis

sion

s (to

ns/y

ear)

Coastal Actual FCCU SO2 Emissions

Date of Lodging: 9/30/20031,000

900

800

700

600

500

400

300

200

100

0 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

Eagle Point (Westville)

Eagle Point hard limit (Dec)


Coastal Actual FCCU NOx EmissionsDate of Lodging: 9/30/2003

1997 1998 1999 2000 2001 2002 2003 2004 2005 2006

0

20

40

60

80

100

120

FCC

U N

Ox

Emis

sion

s (to

ns/y

ear)

Eagle Point (Westville)

Future Events - Eagle Point final limit (Apr 2008)


Recent SettlementsRecent SettlementsChevron

October 2003

� 5 refineries in California, Mississippi, Utah and Hawaii � $275 million in injunctive relief � Annual Reductions � 3,300 tons of NOx � 6,300 tons of SO2

� Penalty: $3.5 million � SEPs: $4 million � Co-Plaintiffs: Hawaii, Mississippi Commission on

Environmental Quality, Utah and Bay Area Air QualityManagement District


Chevron FCCU Emissions Reduction Compliance DatesDOL Oct 2003 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

El Segundo FCCU SO2

FCCU NOX

� �

S Hawaii

FCCU SO2

FCCU NOX

� �

U

�

S Pascagoula

FCCU SO2

FCCU NOX

�

U

�

S Richmond

FCCU SO2

FCCU NOX S

� �

Salt Lake City FCCU SO2

FCCU NOX U

� 1

S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:1Salt Lake City: If feed hydrotreating and SO2 additives are unable to meet the 12/2008 hard limit, WGS must be used to meet the hard limit by 12/2010.


Chevron Emissions Controls MilestonesSO2 Interim Limit: 35 ppm

El Segundo FCCU SO2 Interim Limit: 100 ppm

Pascagoula FCCU NOx Limit: 20/40 ppm

Richmond FCCU PM Limit: 1.0 lb PM/1,000

lbs coke burned Hawaii FCCU

Pascagoula FCCURichmond FCCU

Salt Lake City FCCUCO Limit: 100/500 ppm

Richmond FCCU CO Limit: 500 ppm

Hawaii FCCUPascagoula FCCU

Salt Lake City FCCU

PM Limit: 0.5 lbs PM/1,000 lbs coke burnedEl Segundo

FCCU

Legend FCCU Upcoming

Milestones FCCU Completed

Milestones





SO2 Final Limit: 25/50 ppm El Segundo

FCCU

SO2 Interim Limit: 75 ppm Hawaii FCCU

SO2 Final Limit: 25/50 ppm Pascagoula

FCCU

Date of Lodging


2003

Caustic Scrubber Installed

Hawaii Sulfur Recovery Plant

2004 2005

Install CarbonCanisters in

Series as Part of Benzene

Waste NESHAP

2006

Re-Route Sulfur Pit EmissionsSalt Lake City

Sulfur Recovery Plant

2007 2008

66% NOx Reductions


2009 2010 2011




Recent SettlementsRecent SettlementsCITGO October 2004

� 5 refineries in Georgia, Texas, Louisiana and New Jersey � $320 million in injunctive relief � Annual Reductions � 7,100 tons of NOx � 23,250 tons of SO2

� Penalty: $3.6 million � SEPs: $5 million � Co-Plaintiffs: Georgia, Illinois, Louisiana and New Jersey


CITGO FCCU Emissions Reduction Compliance DatesDOL Oct 2004 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Corpus Christi East 1 FCCU SO2

FCCU NOX U

� �

S Corpus Christi East 2

FCCU SO2

FCCU NOX U

�

S

�

Lake Charles A FCCU SO2

FCCU NOX

�

U

�

S Lake Charles B

FCCU SO2

FCCU NOX

��

U S Lake Charles C

FCCU SO2

FCCU NOX

��

U S Lemont

FCCU SO2

FCCU NOX

��

U S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or hard limits). Footnotes:Corpus Christi East 1: If FCCU is not converted to full-burn, hard limits are effective 12/31/2006.Lemont: If FCCU is not converted to full-burn, hard limits are effective 12/31/2007.


CITGO Emissions Controls Milestones

2004 2005 2006 2007 2008

66% NOx Reductions


NOx Limit 20/40 ppm or Convert to Full Burn Corpus Christi FCCU 1

WGS Installed with SO2 Limit: 25/50 ppm Lake Charles FCCU B

PM Limit: 1.0 lbs PM/1,000 lbs coke burned Corpus Christi FCCU 1 Lake Charles FCCU B

Converted to Full Burn Lemont FCCU WGS Installed

Lake Charles FCCU C Lemont FCCU

PM Limit: 1.0 lb PM/ 1,000 lb coke burned Lake Charles FCCU C

Lemont FCCU

Tail Gas Unit Installed

Lemont Sulfur Recovery Plant



CO Limit: 100/500 ppm Lake Charles

FCCU A Lake Charles

FCCU B Lake Charles

FCCU C

CO Limit:

100/500 ppm

Corpus Christi

FCCU 1

NOx Interim Limit: 23/ 60 ppm

Corpus Christi FCCU 2 PM Limit: 1.0 lb PM/

1,000 lbs coke burned Corpus Christi FCCU 2

PM Limit: 1.0 lbs PM/1,000 lbs coke burned Lake Charles

FCCU A

Low-NOx Burners Installed

Lemont FCCU CO Boiler

SO2 Limit: 3.5 lb SO2/ ton acid

produced Lake Charles Sulfuric Acid

Plant

CO Limit: 100/500 ppm Corpus Christi FCCU 2

Lemont FCCU

Eliminate Fuel Oil Burning


2009 2010 2011

Date of Lodging





Milestones




Q3 2013


Recent SettlementsRecent SettlementsConocoPhillips

January 2005

� 11 refineries in Louisiana, New Jersey, Washington, Texas,California, Pennsylvania and Illinois

� $525 million for injunctive relief � Annual Reductions


� Penalty: $4.5 million � SEPs: $10 million � Co-Plaintiffs: Illinois, Louisiana, New Jersey, Commonwealth

of Pennsylvania and Northwest Clean Air Agency


ConocoPhillips FCCU Emissions Reduction Compliance DatesDOL Jan 2005 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Alliance FCCU SO2

FCCU NOX

��

U S1

Bayway FCCU SO2

FCCU NOX

�

U S Borger 29

FCCU SO2

FCCU NOX

� 2

U S3

Borger 40 FCCU SO2

FCCU NOX

� 2

U S3

Ferndale FCCU SO2

FCCU NOX

�

U S Los Angeles-Wilmington

FCCU SO2

FCCU NOX U

� �

S Sweeny 3

FCCU SO2

FCCU NOX

�

US

�

Sweeny 27 FCCU SO2

FCCU NOX

�

U

�

S Trainer

FCCU SO2

FCCU NOX

��

U S Wood River 1

FCCU SO2

FCCU NOX

��

U S Wood River 2

FCCU SO2

FCCU NOX

��

U S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or ha Footnotes: 1Alliance: If SNERT is installed, compliance date is 3/2015; if SNERT is not installed, compliance date is 12/2009. 2Borger 29, Borger 40: ConocoPhillips notified EPA pursuant to paragraph 58 that the CO boilers will be decommissioned, the FCCUs converted to full burn, and the FCCU feed high pressure hydrotreated. ConocoPhillips will take SO2 hard limits. 3Borger 29, Borger 40: ConocoPhillips notified EPA pursuant to paragraph 39 that the CO boilers will be decommissioned, the FCCUs converted to full burn, and the FCCU feed high pressure hydrotreated. ConocoPhillips will implement a NOx additive program.


ConocoPhillips Emissions Controls Milestones


Recent SettlementsRecent SettlementsSunoco

June 2005

� 4 refineries in Pennsylvania, Ohio and Oklahoma � $350 million in injunctive relief � Annual Reductions


� Penalty: $3 million � SEPs: $3.9 million � Co-Plaintiffs: Pennsylvania, City of Philadelphia, Oklahoma

and Ohio


Sunoco FCCU Emissions Reduction Compliance DatesDOL Jun 2005 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Marcus Hook FCCU SO2

FCCU NOX

��

S Philadelphia 1232

FCCU SO2

FCCU NOX

��

S Philadelphia 868

FCCU SO2

FCCU NOX

Toledo FCCU SO2

FCCU NOX

��

S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or ha


Sunoco Emissions Controls Milestones

2005 2007 2008 66% NOx

Reductions from Heaters and Boilers

SCR Installed with NOx Limit: 20/40 ppm

Toledo FCCU WGS Installed with SO2

Limit: 25/50 ppm Marcus Hook FCCU



Philadelphia FCCU 1232 WGS Installed with SO2

Limit: 25/50 ppm Philadelphia FCCU 1232

CO Limit: 500 ppm Philadelphia FCCU 1232

Marcus Hook FCCU Toledo FCCU

CO Limit: 100 ppm Philadelphia FCCU 868

2nd Claus Train and Tail Gas Units Installed

Toledo Sulfur Recovery Plant

2009 2011 2012

Date of Lodging


Marcus Hook FCCU WGS Installed with SO2

Limit: 25/50 ppm Toledo FCCU

Heaters and Boilers Subject to NSPS Subparts A and J

Toledo and Philadelphia Eliminate Fuel Oil Burning

in Heaters and Boilers


2006 2010 2013

Legend


Heaters and Boilers

Sulfur Recovery Plants Subject to NSPS Subparts A and J

Marcus Hook Philadelphia

Toledo




Recent SettlementsRecent SettlementsValero June 2005

� 14 refineries in California, Colorado, Louisiana, New Jersey, Oklahomaand Texas

� $700 million in injunctive relief � Annual Reductions


� Penalty: $5.5 million � SEPs: $5.5 million � Co-Plaintiffs: Colorado, Louisiana, New Jersey, Oklahoma and Texas � Suncor Energy (U.S.A.) Inc. acquired the Denver, Colorado refinery in

2005 (integrated with adjacent refinery previously acquired froConocoPhillips in 2003)


Valero FCCU Emissions Reduction Compliance DatesDOL Jun 2005 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Ardmore FCCU SO2 ��

Benicia FCCU FCCU SO2 � �

Benicia Coker FCCU SO2 � �

Corpus Christi East FCCU SO2 � � 2

Corpus Christi West FCCU SO2 �

Denver FCCU SO2 � � 2

Houston FCCU SO2

FCCU NOX

��

US Krotz Springs

FCCU SO2 � � McKee FCCU

FCCU SO2 � � McKee Sulfuric Acid Plant

FCCU SO2 �� Paulsboro

FCCU SO2

FCCU NOX

� 1

S St. Charles

FCCU SO2

FCCU NOX

�

S Texas City

FCCU SO2

FCCU NOX

� 1

US Three Rivers

FCCU SO2 �� Wilmington

FCCU SO2

FCCU NOX S

� � 2

Tesoro Golden Eagle FCCU SO2

FCCU NOX

�

S Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or ha Footnotes:1Paulsboro, Texas City: Compliance dates for WGS and SO2 final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of the second quarter 2006.2Corpus Christi East, Denver, Wilmington: One refinery must install WGS to meet hard limits in 2010 while the other refineries must use SO2 reducing additives. A non-selected refinery can take hard limits in lieu of using additives.By 12/2010 one of the ultra-low NOx regenerators at either Paulsboro, St. Charles, or Wilmington must meet hard limits for NOx.System wide coke burn-weighted average NOx interim limit must is effective 3/2009 to include Ardmore, Corpus Christi East, Corpus Christi West, Denver, Houston, Krotz Springs, McKee, Paulsboro, St. Charles, Texas City, Three Rivers, Wilmington, and Tesoro GoldenEagle. The final system wide coke-burn weighted average NOx limit is effective 3/2012.


94

Valero Emissions Controls Milestones

Updated 03/21/06 - Subject to Revision

Recent SettlementsRecent SettlementsExxonMobil

October 2005

� 7 refineries in California, Illinois, Montana, Texas and Louisiana

� $570 million in injunctive relief � Annual Reductions � 11,000 tons of NOx � 42,000 tons of SO2

� Penalty: $8.7 million � SEPs: $9.7 million � Co-Plaintiffs: Illinois, Louisiana and Montana


ExxonMobil FCCU Emissions Reduction Compliance DatesDOL Oct 2005 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015

Baton Rouge FCCU SO2

FCCU NOX

�

S2

Baytown 2 FCCU SO2

FCCU NOX U

�

S Baytown 3

FCCU SO2

FCCU NOX

� 1

U S Beaumont

FCCU SO2

FCCU NOX

� 1

U S Billings

FCCU SO2

FCCU NOX

�

S

�

Joliet FCCU SO2

FCCU NOX

�

S Torrance

FCCU SO2

FCCU NOX

� 1

S2

Chalmette FCCU SO2

FCCU NOX

�

S3

Notes: SO2: �=interim hard limit, �= final hard limits, �= hardware installation, �= hardware limits effective, �= start of additives, �= additives demonstration report deadline, Slashes ( / ) indicate combinations (e.g. either additives or hard limits). NOX: U= interim hard limit, S = hard limits, U= hardware installation, S = hardware limits effective, U= start of additives and/or low NOx COPs, S = additives demonstration report deadline , Slashes ( / ) indicate combinations (e.g. either additives or ha Footnotes:1Torrance, Beaumont, Baytown FCCU 3: Compliance dates for SO2 final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of 2006.2Torrance, Baton Rouge: Compliance dates for NOx final limits are based on Date of Entry; timeline assumes Consent Decree will be entered by the end of 2006.3Chalmette: If additives are found to be effective, compliance date is 6/30/2007, if additives are not effective, compliance date is 12/31/2008.


ExxonMobil & Chalmette Emissions Controls Milestones



Emissions Monitoring Requirements


Types of Emissions MonitoringTypes of Emissions Monitoring MethodsMethods

� Continuous Emissions Monitoring System (CEMS) � Installed, certified, maintained and operated in accordance with 40 CFR

§§ 60.11, 60.13, and Part 60 Appendix A � Relative Accuracy Audit (RAA) or Relative Accuracy Test Audit (RATA)

conducted once every three years � Cylinder Gas Audit (CGA) conducted the quarters when RAA or RATA

are not � Continuous Opacity Monitoring System (COMS)

� Operate continuous opacity monitoring system (COMS) in accordancewith 40 CFR §§ 60.11, 60.13, and Part 60 Appendix A

� Parametric or Predictive Emissions Monitoring System (PEMS) � Mathematical model calculating pounds pollutant per mmBTU using

heater and boiler operating parameters � Consistent with CEMS data frequency requirements of 40 CFR Part 60

� Stack Tests � Conducted in accordance with 40 CFR Part 60 Appendix A or EPA-

approved alternative method


Fluid Catalytic Cracking UnitFluid Catalytic Cracking Unit (FCCU) Emissions Monitoring(FCCU) Emissions Monitoring

� SO2, NOx, CO, and O2: CEMS � CEMS installed prior to conducting performance tests � Calibration drifts of CEMS checked daily � CEMS sample, analyze, and record data for each successive 15-

minute period � 1-hour averages computed using the 15-minute CEMS data

� PM: Stack Tests � Stack testing according to 40 CFR Part 60 Appendix A Methods

5B or 5F; typically annually, but frequency can vary by consent decree

� Some consent decrees also require COMS for opacity


Heater and BoilerHeater and BoilerEmissions MonitoringEmissions Monitoring

� Capacity greater than 150 mmBTU/hr � NOx, CO, and O2: CEMS

� Capacity between 100 and 150 mmBTU/hr � NOx, CO, and O2 : CEMS or PEMS

� Capacity less than 100 mmBTU/hr � NOx, CO, and O2: stack tests or portable continuous analyzer


Sulfur Recovery Plant (SRP)Sulfur Recovery Plant (SRP) Emissions MonitoringEmissions Monitoring

� SO2: CEMS or EPA-approved alternative � Monitor and report all excess emissions as required by 40 CFR

§§ 60.7(c), 60.13, and 60.105(a)(5), (6), or (7) � Develop and implement a Preventative Maintenance and

Operation Plan to reduce SO2 emissions using good air pollution control practices


Hydrocarbon FlareHydrocarbon FlareEmissions MonitoringEmissions Monitoring

� One of the following requirements apply: � Install and operate CEMS or PEMS � Control flaring by operating flare gas recovery system to control

continuous or routine flaring � Eliminate the routes of generated fuel gases and only flare:

� Process upset gases; � Fuel gas released as a result of relief valve leakage; or � Gas released due to a malfunction

� Eliminate the routes of generated fuel gases and monitor the flare with CEMS or a flow meter


Benzene Emissions MonitoringBenzene Emissions Monitoring� 40 CFR Part 61 Subpart FF Benzene Waste NESHAP

(BWON) � Sampling for benzene concentration according to 40 CFR

§61.355(c)(3) � If Total annual benzene (TAB) emissions less than 10 MG/yr,

then exempt from BWON � If TAB emissions greater than 10 MG/yr, then develop and

implement a plan identifying a strategy to ensure compliance with BWON


Leak Detection and Repair (LDAR)Leak Detection and Repair (LDAR) Emissions MonitoringEmissions Monitoring

� Develop and implement a program to achieve and maintain compliance with state and federal LDAR regulations (e.g., 40 CFR Part 60 Subparts VV and GGG)

� Program must include: � Refinery wide leak rate goal � Identification of all equipment with the potential to leak � Procedures to identify, repair, and track leaky equipment � LDAR audits


Implementation of DecreesImplementation of DecreesVolume of “Deliverables” Submitted under Decrees

“Deliverables” Include Reports of Flaring Incidents and Corrective Action, Biennial Reporting, etc.

F

Y2002

F

Y2003

F

Y2004

F

Y2005 (30 refineries) (38 refineries) (42 refineries) (62 refineries)

854 753

1619 1508

2364

2231

3078 2879

0

500

1000

1500

2000

2500

3000

3500

Total # of Deliverables Submitted

Total # Responded to On-Time


Implementation of DecreesImplementation of DecreesImprovements in EPA Responsiveness

88.2 93.2 94.4 93.53

0

20

40

60

80

100

FY2002 FY2003 FY2004 FY2005

On-Time Response Rate (%)


Next StepsNext Steps

� Continue work toward achieving goal of 80% of refining industry covered by global settlement, referral to DOJ, or filed enforcement action.

� Negotiations currently ongoing with refiners representing approximately 20% of industry

� Maintain focus on implementation of Consent Decrees to achieve expected emissions reductions.



Link and Contact Information Link and Contact Information

EPA National Petroleum Refinery Initiative (NPRI) Website: www.epa.gov/compliance/npriresources

EPA Headquarters Technical Contact: Patrick Foley, Senior Environmental Engineer, (202) 564-7978

EPA Headquarters Legal Contact: James Jackson, Senior Attorney Advisor, (202) 564-2002

Published August 2008

Refining Capacity ReportJanuary 1, 2008

NPRA United States Refiningand Storage Capacity Report


Locations ofU.S. Refineries 2008

PADD V PADD IV PADD II PADD I

PADD III

Large: Over 75,000 B/D

Small: Under 75,000 B/D



The following table lists the total U.S. refining capacityfor the past five years:

January 1 Total Capacity inThousands of Barrels Per Calendar Day

2004 2005 2006 2007 2008U.S. 16,894 17,125 17,339 17,444 17,594Puerto Rico 111 110 78 78 78Virgin Islands 495 495 495 500 500

This summary of petroleum refineries in the UnitedStates and U.S. territories is taken from the Departmentof Energy’s Petroleum Supply Annual 2008, publishedJune, 2008. Capacity data are reproduced byNPRA as a courtesy to members. The data enclosed,as well as other DOE refining statistics, are availableelectronically from DOE (http://www.eia.doe.gov).For information, call EIA’s National Energy InformationCenter at 202.586.8800, e-mail at: [email protected]

a The total count of operational refineries increased to 150 becauseEIA reclassified an existing facility (Equistar Chemicals LP ,Channelview, TX), as a petroleum refinery.

The enclosed statistics provide U.S. refining and storagecapacity data as reported by the DOE EnergyInformation Administration in their 2008 PetroleumSupply Annual. These data, along with other DOEstatistics, are also available electronically. (See the noteat the bottom of this page for details.) This report isalso available on the NPRA web site (www.npra.org)under the Online Store.

On January 1, 2008, there were 150a operable refineriesin the United States (excluding Puerto Rico and theVirgin islands) with total crude distillation capacity of17.6 million barrels per calendar day and 18.6 millionbarrels per stream day. Of these, 146 refineries wereoperating on January 1, 2008, with operating capacitylisted at 17.2 million barrels per calendar day and18.2 million barrels per stream day.

The Energy Information Administration reports thatduring 2007, one U.S. refinery with a capacity of16.7 thousand barrels per calendar day was shut down(p. 50) and one U.S. refinery with a capacity of12.0 thousand barrels per calendar day was reactivated.

Table of Contents


44 Table 7Operable Production Capacity of PetroleumRefineries, January 1, 1981 to January 1, 2008

45 Table 8Working Storage Capacity at OperableRefineries by PAD District as of January 1, 2008

46 Table 9Shell Storage Capacity at Operable Refineriesby PAD District as of January 1, 2008

47 Table 10Capacity and Fresh Feed Input to SelectedDownstream Units at U.S. Refineries, 2006-2008

48 Table 11Refinery Receipts of Crude Oil by Method ofTransportation by PAD District, 2007

49 Table 12Fuel Consumed at Refineries byPAD District, 2007

50 Table 13New, Reactivated, and Shutdown Refineriesduring 2007

51 Table 14Refinery Sales during 2007

52 Table 15Refineries Permanently Shutdown byPAD District between 1990 and 2007

Appendices57 Appendix A - District Descriptions and Maps61 Appendix B - Explanatory Notes

Glossary67 Definitions of Petroleum Products and

Other Terms

1 Table 1Number and Capacity of Operable PetroleumRefineries by PAD District and State as ofJanuary 1, 2008

3 Table 2Production Capacity of Operable PetroleumRefineries by PAD District and State as ofJanuary 1, 2008

4 Directory of Operable Petroleum Refineries inTables 3 and 4

5 Table 3Capacity of Operable Petroleum Refineries byState as of January 1, 2008

29 Directory of Operable Petroleum Refineries inTables 3 and 4

30 Table 4Production Capacity of Operable PetroleumRefineries by State as of January 1, 2008

37 Table 5Refiners’ Operable Atmospheric Crude OilDistillation Capacity as of January 1, 2008

37 Companies with Capacity Over 100,000 bbl/cd

40 Companies with Capacity 30,001 to100,000 bbl/cd

40 Companies with Capacity 10,001 to30,000 bbl/cd

41 Companies with Capacity 10,000 bbl/cdor Less

43 Table 6Operable Crude Oil and DownstreamCharge Capacity of Petroleum Refineries,January 1, 1981 to January 1, 2008

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Appendix A:District Descriptionsand Maps


Energy Information Administration, Refinery Capacity 2008

57

Appendix A

District Descriptions and Maps

The following are the Refining Districts which make up the Petroleum Administration for Defense (PAD) Districts.

PAD District I

East Coast: District of Columbia and the States of Maine, New Hampshire, Vermont, Massachusetts, Rhode Island, Connecticut, New Jersey, Delaware, Maryland, Virginia, North Carolina, South Carolina, Georgia, Florida, and the following counties of the State of New York: Cayuga, Tompkins, Chemung, and all counties east and north thereof. Also the following counties in the State of Pennsylvania: Bradford, Sullivan, Columbia, Montour, Northumberland, Dauphin, York, and all counties east thereof.

Appalachian No. 1: The State of West Virginia and those parts of the States of Pennsylvania and New York not included in the East Coast District.

Sub-PAD District I

New England: The States of Connecticut, Maine, Massachusetts, New Hampshire, Rhode Island and Vermont.

Central Atlantic: The District of Columbia and the States of Delaware, Maryland, New Jersey, New York, and Pennsylvania.

Lower Atlantic: The States of Florida, Georgia, North Carolina, South Carolina, Virginia and West Virginia.

PAD District II

Indiana-Illinois-Kentucky: The States of Indiana, Illinois, Kentucky, Tennessee, Michigan, and Ohio.

Minnesota-Wisconsin-North and South Dakota: The States of Minnesota, Wisconsin, North Dakota and South Dakota.

Oklahoma-Kansas-Missouri: The States of Oklahoma, Kansas, Missouri, Nebraska, and Iowa.

PAD District III

Texas Inland: The State of Texas except the Texas Gulf Coast District.

Texas Gulf Coast: The following counties of the State of Texas: Newton, Orange, Jefferson, Jasper, Tyler, Hardin, Liberty, Chambers, Polk, San Jacinto, Montgomery, Harris, Galveston, Waller, Fort Bend, Brazoria, Wharton, Matagorda, Jackson, Victoria, Calhoun, Refugio, Aransas, San Patricio, Nueces, Kleberg, Kenedy, Willacy, and Cameron.

Louisiana Gulf Coast: The following Parishes of the State of Louisiana: Vernon, Rapides, Avoyelles, Pointe Coupee, West Feliciana, East Feliciana, Saint Helena, Tangipahoa, Washington, and all Parishes south thereof. Also the following counties of the State of Mississippi: Pearl River, Stone, George, Hancock, Harrison, and Jackson. Also the following counties of the State of Alabama: Mobile and Baldwin.

North Louisiana-Arkansas: The state of Arkansas and those parts of the States of Louisiana, Mississippi, and Alabama not included in the Louisiana Gulf Coast District.

New Mexico: The State of New Mexico.

PAD District IV

Rocky Mountain: The States of Montana, Idaho, Wyoming, Utah, and Colorado.

PAD District V

West Coast: The States of Washington, Oregon, California, Nevada, Arizona, Alaska, and Hawaii

Appendix B:Explanatory Notes



Appendix B

Explanatory Notes

Form EIA-820: Annual Refinery Report Refinery capacity data collection was begun in 1918 by the Bureau of Mines, then in the Department of Commerce, and was operated on a voluntary basis until 1980. In 1980, the mandatory Energy Information Administration (EIA) Form EIA-177, Capacity of Petroleum Refineries, was implemented. Information on refining capacity was expanded to include not only current year operations, but two-year projections, and refinery input/production data. Working storage capacity data was also added to the form and product categories were added for total coverage. Information on refinery downstream facilities was expanded to include a breakdown of thermal operations and to add vacuum distillation, catalytic hydrorefining and hydrotreating. Production capacity was also added to include information on isomerization, alkylation, aromatics, asphalt/road oil, coking, lubricants and hydrogen. In 1983, the form was revised to improve the consistency and quality of the data collected by the EIA and redesignated as Form EIA-820, “Annual Refinery Report.” Two sections for data previously reported monthly were added: (1) refinery receipts of crude oil by method of transportation, and (2) fuels consumed for all purposes at refineries. Also, the second year projections on refining capacity were eliminated. As a result of a study conducted by the EIA evaluating motor gasoline data collected by the Federal Highway Administration (FHWA) and by the EIA, motor gasoline blending plants were included for the first time in the respondent frame in order to produce more accurate statistics on the production of motor gasoline. In 1987, the form was revised to reduce respondent burden and to better reflect current refinery operations through updated terminology. Information on projected input/production of refinery processing facilities was deleted. Several categories under catalytic hydrotreating were combined: naphtha and reformer feeds were combined into a single category as well as residual fuel oil and other. Thermal cracking types, gas oil and “other” were also combined into a single category. Catalytic reforming types, conventional and bi-metallic were replaced with low and high pressure processing units. Two

new categories were added: fuels solvent deasphalting was added to downstream charge capacity and sulfur recovery was added to production capacity. In 1994, the form was revised to enable EIA to calculate utilization rates for certain downstream processing units and to reflect storage capacity of fuels mandated by the Clean Air Act Amendments of 1990. Additions to the form included calendar day downstream charge capacity for fluid and delayed coking, catalytic cracking, and catalytic hydrocracking. Also storage capacity categories for reformulated, oxygenated, and other finished motor gasoline were added, as well as oxygenate storage capacity and separate categories for high and low sulfur distillate fuel oil. In 1995, motor gasoline blending plants were dropped from the survey frame, since by this time, the only section of the form that applied to them was working and shell storage capacity. Also in 1995, a decision was made to no longer collect storage capacity from shutdown refineries; therefore, these refineries were also eliminated from the survey frame. In 1996, the survey was moved to a biennial schedule (every other year) and was renamed “Biennial Refinery Report.” The survey was not conducted for January 1, 1996 or January 1, 1998. Respondents were not required to submit data for crude oil and petroleum products consumed at refineries during 1995 and 1997. These data are available from the Form EIA-810, “Monthly Refinery Report.” The requirement to submit data for refinery consumption of natural gas, coal, and purchased steam and electricity on the Form EIA-820 remained. In 2000, the survey was moved to an annual schedule. In 2004, the survey form was amended to reflect the increasing emphasis on the removal of sulfur from transportation fuels. In 2008, Table 15, “Refineries Permanently Shutdown by PAD District Between January 1, 1990 and January 1, 2007” was added to the report.

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Respondent Frame The respondent frame consists of all operating and idle petroleum refineries (including new refineries under construction),located in the 50 States, the District of Columbia, Puerto Rico, the Virgin Islands, Guam and other U.S. possessions. As of January 1, 2006, there were 151 refineries. The respondent frame is maintained by monitoring the monthly Form EIA-810, “Monthly Refinery Report,” and industry publications for changes and developments in the petroleum industry such as refinery sales, mergers and new operations. Description of Survey Form The Form EIA-820 is used to collect data on fuels consumed for all purposes at the refinery during the preceding year; refinery receipts of crude oil by method of transportation during the preceding year; current and next year projections for operable atmospheric crude oil distillation capacity, downstream charge capacity and production capacity; and current year working and shell storage capacity for crude oil and petroleum products at the refinery. Collection Methods The Form EIA-820 is sent to respondents in December. Survey forms can be submitted by electronic mail or facsimile. Completed forms are required to be postmarked by the 15th day of February of the current report year. Receipt of the reports is monitored using an automated respondent mailing list. Telephone follow-up calls are made to secure responses from those companies failing to report by February 15th. Response Rate The response rate for the Form EIA-820 is normally very high. Data are estimated and non-compliance procedures are implemented for those companies still not reporting data by close-out for the report year. Data Imputation Imputation is performed for companies that fail to file prior to the publication deadline. For the January 1, 2008 survey, there were no nonrespondents. When nonresponse occurs, values for these companies are imputed from data reported on the most recent year’s Form EIA-820 and/or from data reported on Form EIA-810, “Monthly Refinery Report,” for that company. For most surveyed items, the value imputed for nonrespondents is the value that company reported on the Form EIA-820 for the most recent year. For three categories of information however, the imputed value is also based on their data from the Form EIA-810 as follows:

Section 2: Refinery Receipts of Crude Oil by Method of Transportation The imputation methodology for this section is based on data reported on both the monthly Form EIA-810 and the annual Form EIA-820. Annual refinery receipts of domestic and foreign crude oil for a nonrespondent are imputed by aggregating the values for the refinery on the monthly survey. These values are allocated to the method of transportation by using the percentages reported for the refinery in the previous year. The difference between the values reported on the two surveys by all respondents in 2008 was about 0.23 percent. Section 3: Operable and Storage Capacity as of January 1 Operable atmospheric crude oil distillation capacity in barrels per calendar day is collected on the monthly Form EIA-810 as of the first day of each month and on the annual Form EIA-820 as of January 1. As part of the editing process for the Form EIA-820, these two values are compared. Companies are contacted and any discrepancies are resolved by the time of publication. Imputed values for operable atmospheric crude oil distillation capacity in barrels per calendar day are taken directly from the January Form EIA-810. A barrels per stream day capacity is then derived by dividing the reported barrels per calendar day capacity by .95. Current year and projected year data for downstream charge capacity, production capacity, and data for working and shell storage capacity are taken directly from the previous year’s annual report. Confidentiality The Office of Legal Counsel of the Department of Justice concluded on March 20, 1991, that the Federal Energy Administration Act requires the Energy Information Administration to provide company-specific data to the Department of Justice, or to any other Federal agency when requested for official use, which may include enforcement of Federal law. The information contained on this form may also be made available, upon request, to another component of the Department of Energy (DOE), to any Committee of Congress, the General Accounting Office, or other Congressional agencies authorized by law to receive such information. A court of competent jurisdiction may obtain this information in response to an order. Information on operable atmospheric crude oil distillation capacity, downstream charge capacity, and production capacity (Sections 3, 4 and 5) on Form EIA-820 are not considered as confidential, and historically have not been treated as such. Company identifiable data are published in the Petroleum

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Supply Annual (PSA) 2002, Volume 1, Tables 38, 39, and 40. Other data (Sections 1, 2, 6 and respondent information) on the Form EIA-820 are kept confidential and not disclosed to the public to the extent that it satisfies the criteria for exemption under the Freedom of Information Act (FOIA), 5 U.S.C.552, Department of Energy (DOE) regulations, 10 C.F.R.1004.11, implementing the FOIA, and the Trade Secrets Act, 18 U.S.C.1905. Upon receipt of a request for this information under the FOIA, the DOE shall make a final determination whether the information is exempt from disclosure in accordance with the procedures and criteria provided in the regulations. To assist us in this determination, respondents should demonstrate to the DOE that, for example, their information contains trade secrets or commercial or financial information whose release would be likely to cause substantial harm to their company’s competitive position. A letter accompanying the submission that explains (on an element-by-element basis) the reasons why the information would be likely to cause the respondent substantial competitive harm if released to the public would aid in this determination. A new justification does not need to be provided each time information is submitted on the form, if the company has previously submitted a justification for that information and the justification has not changed. The data collected on Form EIA-820, “Annual Refinery Report,” is used to report aggregate statistics on and conduct analyses of the operation of U.S. petroleum refineries. The data appear in EIA publications such as PSA, and the Annual Energy Review. Company specific data are also provided to other DOE offices for the purpose of examining specific refinery operations in the context of emergency response planning and actual emergencies. The tables pertaining to refinery receipts of crude oil by method of transportation and fuels consumed at the refinery published in the PSA are not subject to statistical nondisclosure procedures. Thus, there may be some table cells which are based on data from only one or two respondents, or which are dominated by data from one or two large respondents. In these cases, it may be possible for a knowledgeable user of the data to make inferences about the data reported by a specific respondent.

Quality Control There are two types of errors usually associated with data produced from a survey -sampling errors and nonsampling errors. Because estimates from the Form EIA-820 survey are based on a complete census of the frame of petroleum refineries, there is no sampling error in the data presented in this report. The data, however, are subject to nonsampling errors. Nonsampling errors are those which can arise from: (1) the inability to obtain data from all companies in the frame or sample (nonresponse) and the method used to account for nonresponses; (2) definitional difficulties and/or improperly worded questions which lead to different interpretations; (3) mistakes in recording or coding the data obtained from respondents; and (4) other errors of collection, response, coverage, and estimation. Quality control procedures are employed in the collection and editing operations to minimize misrepresentation and misreporting. Nonresponse follow-up procedures are employed to reduce the number of nonrespondents, and procedures employed to impute missing data, introduce a minimal amount of error, given the relatively small volume of imputed data. Resubmissions Resubmissions are required whenever an error greater than 5 percent of the true value is discovered. In the event of a reporting error, company reports are updated after contact with the company and are followed up by corrected report resubmissions. Late submissions or resubmissions received after the publication date are entered into a “working” file. This file contains the most up-to date data for the Form EIA-820 and is used to edit next year’s data.

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Glossary



Definitions of Petroleum Products and Other Terms (Revised July 2008)

Alcohol. The family name of a group of organic chemical compounds composed of carbon, hydrogen, and oxygen. The series of molecules vary in chain length and are composed of a hydrocarbon plus a hydroxyl group; CH3(CH2)n-OH (e.g., methanol, ethanol, and tertiary butyl alcohol). Alkylate. The product of an alkylation reaction. It usually refers to the high octane product from alkylation units. This alkylate is used in blending high octane gasoline. Alkylation. A refining process for chemically combining isobutane with olefin hydrocarbons (e.g., propylene, butylenes) through the control of temperature and pressure in the presence of an acid catalyst, usually sulfuric acid or hydrofluoric acid. The product, alkylate, an isoparaffin, has high octane value and is blended with motor and aviation gasoline to improve the antiknock value of the fuel. API Gravity. An arbitrary scale expressing the gravity or density of liquid petroleum products. The measuring scale is calibrated in terms of degrees API; it may be calculated in terms of the following formula: Degrees API = 141.5/sp.gr.60° F/60 °F -131.5 The higher the API gravity, the lighter the compound. Light crudes generally exceed 38 degrees API and heavy crudes are commonly labeled as all crudes with an API gravity of 22 degrees or below. Intermediate crudes fall in the range of 22 degrees to 38 degrees API gravity. Aromatics. Hydrocarbons characterized by unsaturated ring structures of carbon atoms. Commercial petroleum aromatics are benzene, toluene, and xylenes (BTX). Asphalt. A dark-brown-to-black cement-like material containing bitumens as the predominant constituent obtained by petroleum processing; used primarily for road construction. It includes crude asphalt as well as the following finished products: cements, fluxes, the asphalt content of emulsions (exclusive of water), and petroleum distillates blended with asphalt to make cutback asphalts. Note: The conversion factor for asphalt is 5.5 barrels per short ton. ASTM. The acronym for the American Society for Testing and Materials.

Atmospheric Crude Oil Distillation. The refining process of separating crude oil components at atmospheric pressure by heating to temperatures of about 600 degrees Fahrenheit to 750 degrees Fahrenheit (depending on the nature of the crude oil and desired products) and subsequent condensing of the fractions by cooling. Aviation Gasoline (Finished). A complex mixture of relatively volatile hydrocarbons with or without small quantities of additives, blended to form a fuel suitable for use in aviation reciprocating engines. Fuel specifications are provided in ASTM Specification D 910 and Military Specification MIL-G-5572. Note: Data on blending components are not counted in data on finished aviation gasoline. Aviation Gasoline Blending Components. Naphthas which will be used for blending or compounding into finished aviation gasoline (e.g., straight-run gasoline, alkylate, reformate, benzene, toluene, and xylenes). Excludes oxygenates (alcohols, ethers), butanes, and pentanes.. Oxygenates are reported as other hydrocarbons, hydrogen, and oxygenates. Barrel. A unit of volume equal to 42 U.S. gallons. Barrels Per Calendar Day. The amount of input that a distillation facility can process under usual operating conditions. The amount is expressed in terms of capacity during a 24-hour period and reduces the maximum processing capability of all units at the facility under continuous operation (see Barrels per Stream Day) to account for the following limitations that may delay, interrupt, or slow down production:

the capability of downstream facilities to absorb the output of crude oil processing facilities of a given refinery. No reduction is made when a planned distribution of intermediate streams through other than downstream facilities is part of a refinery’s normal operation; the types and grades of inputs to be processed; the types and grades of products expected to be manufactured; the environmental constraints associated with refinery operations; the reduction of capacity for scheduled downtime due to such conditions as routine inspection, maintenance, repairs, and turnaround; and

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the reduction of capacity for unscheduled downtime due to such conditions as mechanical problems, repairs, and slowdowns.

Barrels Per Stream Day. The maximum number of barrels of input that a distillation facility can process within a 24-hour period when running at full capacity under optimal crude and product slate conditions with no allowance for downtime. Benzene (C6H6). An aromatic hydrocarbon present in small proportion in some crude oils and made commercially from petroleum by the catalytic reforming of naphthenes in petroleum naphtha. Also made from coal in the manufacture of coke. Used as a solvent, in manufacturing detergents, synthetic fibers, and petrochemicals and as a component of high-octane gasoline. Blending Components. See Motor or Aviation Gasoline Blending Components. Blending Plant. A facility which has no refining capability but is either capable of producing finished motor gasoline through mechanical blending or blends oxygenates with motor gasoline. Bonded Petroleum Imports. Petroleum imported and entered into Customs bonded storage. These imports are not included in the import statistics until they are: (1) withdrawn from storage free of duty for use as fuel for vessels and aircraft engaged in international trade; or (2) withdrawn from storage with duty paid for domestic use. BTX. The acronym for the commercial petroleum aromatics benzene, toluene, and xylenes. See individual categories for definitions. Bulk Station. A facility used primarily for the storage and/or marketing of petroleum products which has a total bulk storage capacity of less than 50,000 barrels and receives its petroleum products by tank car or truck. Bulk Terminal. A facility used primarily for the storage and/or marketing of petroleum products which has a total bulk storage capacity of 50,000 barrels or more and/or receives petroleum products by tanker, barge, or pipeline. Butane (C4H10). A normally gaseous straight-chain or branch-chain hydrocarbon extracted from natural gas or refinery gas streams. It includes normal butane and refinery-grade butane and is designated in ASTM Specification D1835 and Gas Processors Association Specifications for commercial butane.

Refinery-Grade Butane (C4H10). A refinery-produced stream that is composed predominantly of normal butane and/or isobutane and may also

contain propane and/or natural gasoline. These streams may also contain significant levels of olefins and/or fluorides contamination. Butylenes (C4H8). An olefinic hydrocarbon recovered from refinery processes. Captive Refinery Oxygenate Plants. Oxygenate production facilities located within or adjacent to a refinery complex. Catalytic Cracking. The refining process of breaking down the larger, heavier, and more complex hydrocarbon molecules into simpler and lighter molecules. Catalytic cracking is accomplished by the use of a catalytic agent and is an effective process for increasing the yield of gasoline from crude oil. Catalytic cracking processes fresh feeds and recycled feeds.

Fresh Feeds. Crude oil or petroleum distillates which are being fed to processing units for the first time. Recycled Feeds. Feeds that are continuously fed back for additional processing.

Catalytic Hydrocracking. A refining process that uses hydrogen and catalysts with relatively low temperatures and high pressures for converting middle boiling or residual material to high-octane gasoline, reformer charge stock, jet fuel, and/or high grade fuel oil. The process uses one or more catalysts, depending upon product output, and can handle high sulfur feedstocks without prior desulfurization. Catalytic Hydrotreating. A refining process for treating petroleum fractions from atmospheric or vacuum distillation units (e.g., naphthas, middle distillates, reformer feeds, residual fuel oil, and heavy gas oil) and other petroleum (e.g., cat cracked naphtha, coker naphtha, gas oil, etc.) in the presence of catalysts and substantial quantities of hydrogen. Hydrotreating includes desulfurization, removal of substances (e.g., nitrogen compounds) that deactivate catalysts, conversion of olefins to paraffins to reduce gum formation in gasoline, and other processes to upgrade the quality of the fractions. Catalytic Reforming. A refining process using controlled heat and pressure with catalysts to rearrange certain hydrocarbon molecules, thereby converting paraffinic and naphthenic type hydrocarbons (e.g., low-octane gasoline boiling range fractions) into petrochemical feedstocks and higher octane stocks suitable for blending into finished gasoline. Catalytic reforming is reported in two categories. They are:

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Low Pressure. A processing unit operating at less than 225 pounds per square inch gauge (PSIG) measured at the outlet separator. High Pressure. A processing unit operating at either equal to or greater than 225 pounds per square inch gauge (PSIG) measured at the outlet separator.

Charge Capacity. The input (feed) capacity of the refinery processing facilities. Coal. A readily combustible black or brownish-black rock whose composition, including inherent moisture, consists of more than 50 percent by weight and more than 70 percent by volume of carbonaceous material. It is formed from plant remains that have been compacted, hardened, chemically altered, and metamorphosed by heat and pressure over geologic time. Commercial Kerosene-Type Jet Fuel. See Kerosene-type Jet Fuel.

Conventional Gasoline. See Motor Gasoline

(Finished). Crude Oil. A mixture of hydrocarbons that exists in liquid phase in natural underground reservoirs and remains liquid at atmospheric pressure after passing through surface separating facilities. Depending upon the characteristics of the crude stream, it may also include:

Small amounts of hydrocarbons that exist in gaseous phase in natural underground reservoirs but are liquid at atmospheric pressure after being recovered from oil well (casinghead) gas in lease separators and are subsequently commingled with the crude stream without being separately measured. Lease condensate recovered as a liquid from natural gas wells in lease or field separation facilities and later mixed into the crude stream is also included; Small amounts of nonhydrocarbons produced from oil, such as sulfur and various metals; Drip gases, and liquid hydrocarbons produced from tar sands, gilsonite, and oil shale.

Liquids produced at natural gas processing plants are excluded. Crude oil is refined to produce a wide array of petroleum products, including heating oils; gasoline, diesel and jet fuels; lubricants; asphalt; ethane, propane, and butane; and many other products used for their energy or chemical content. Crude oil is considered as either domestic or foreign, according to the following:

Domestic. Crude oil produced in the United States or from its “outer continental shelf’ as defined in 43 USC 1331. Foreign. Crude oil produced outside the United States. Imported Athabasca hydrocarbons (tar sands from Canada) are included.

Crude Oil, Refinery Receipts. Receipts of domestic and foreign crude oil at a refinery. Includes all crude oil in transit except crude oil in transit by pipeline. Foreign crude oil is reported as a receipt only after entry through customs. Crude oil of foreign origin held in bonded storage is excluded. Crude Oil Losses. Represents the volume of crude oil reported by petroleum refineries as being lost in their operations. These losses are due to spills, contamination, fires, etc. as opposed to refinery processing losses. Crude Oil Production. The volume of crude oil produced from oil reservoirs during given periods of time. The amount of such production for a given period is measured as volumes delivered from lease storage tanks (i.e., the point of custody transfer) to pipelines, trucks, or other media for transport to refineries or terminals with adjustments for (1) net differences between opening and closing lease inventories, and (2) basic sediment and water (BS&W). Crude Oil Qualities. Refers to two properties of crude oil, the sulfur content and API gravity, which affect processing complexity and product characteristics. Delayed Coking. A process by which heavier crude oil fractions can be thermally decomposed under conditions of elevated temperatures and pressure to produce a mixture of lighter oils and petroleum coke. The light oils can be processed further in other refinery units to meet product specifications. The coke can be used either as a fuel or in other applications such as the manufacturing of steel or aluminum. Desulfurization. The removal of sulfur, as from molten metals, petroleum oil, or flue gases. Petroleum desulfurization is a process that removes sulfur and its compounds from various streams during the refining process. Desulfurization processes include catalytic hydrotreating and other chemical/physical processes such as adsorption. Desulfurization processes vary based on the type of stream treated (e.g. naphtha, distillate, heavy gas oil, etc.) and the amount of sulfur removed (e.g. sulfur reduction to 10 ppm). See Catalytic Hydrotreating.

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Disposition. The components of petroleum disposition are stock change, crude oil losses, refinery inputs, exports, and products supplied for domestic consumption. Distillate Fuel Oil. A general classification for one of the petroleum fractions produced in conventional distillation operations. It includes diesel fuels and fuel oils. Products known as No. 1, No. 2, and No. 4 diesel fuel are used in on-highway diesel engines, such as those in trucks and automobiles, as well as off-highway engines, such as those in railroad locomotives and agricultural machinery. Products known as No. 1, No. 2, and No. 4 fuel oils are used primarily for space heating and electric power generation.

No. 1 Distillate. A light petroleum distillate that can be used as either a diesel fuel or a fuel oil.

No. 1 Diesel Fuel. A light distillate fuel oil that has distillation temperatures of 550 degrees Fahrenheit at the 90-percent point and meets the specifications defined in ASTM Specification D 975. It is used in high-speed diesel engines generally operated under frequent speed and load changes, such as those in city buses and similar vehicles. No. 1 Fuel Oil. A light distillate fuel oil that has distillation temperatures of 400 degrees Fahrenheit at the 10-percent recovery point and 550 degrees Fahrenheit at the 90-percent point and meets the specifications defined in ASTM Specification D 396. It is used primarily as fuel for portable outdoor stoves and portable outdoor heaters.

No. 2 Distillate. A petroleum distillate that can be used as either a diesel fuel or a fuel oil.

No. 2 Diesel Fuel. A fuel that has distillation temperatures of 500 degrees Fahrenheit at the 10-percent recovery point and 640 degrees Fahrenheit at the 90percent recovery point and meets the specifications defined in ASTM Specification D 975. It is used in high speed diesel engines that are generally operated under uniform speed and load conditions, such as those in railroad locomotives, trucks, and automobiles.

Low Sulfur No. 2 Diesel Fuel. No. 2 diesel fuel that has a sulfur level no higher than 0.05 percent by weight. It is used primarily in motor vehicle diesel engines for on-highway use. High Sulfur No. 2 Diesel Fuel. No. 2 diesel fuel that has a sulfur level above 0.05 percent by weight.

No. 2 Fuel Oil (Heating Oil). A distillate fuel oil that has distillation temperatures of 400 degrees Fahrenheit at the 10-percent recovery point and 640 degrees Fahrenheit at the 90-percent recovery point and meets the specifications defined in ASTM Specification D 396. It is used in atomizing type burners for domestic heating or for moderate capacity commercial/industrial burner units.

No. 4 Fuel. A distillate fuel oil made by blending distillate fuel oil and residual fuel oil stocks. It conforms with ASTM Specification D 396 or Federal Specification VV-F-815C and is used extensively in industrial plants and in commercial burner installations that are not equipped with preheating facilities. It also includes No. 4 diesel fuel used for low-and medium-speed diesel engines and conforms to ASTM Specification D 975. No. 4 Diesel Fuel. See No. 4 Fuel. No. 4 Fuel Oil. See No. 4 Fuel.

Electricity (Purchased). Electricity purchased for refinery operations that is not produced within the refinery complex. Ending Stocks. Primary stocks of crude oil and petroleum products held in storage as of 12 midnight on the last day of the month. Primary stocks include crude oil or petroleum products held in storage at (or in) leases, refineries, natural gas processing plants, pipelines, tank farms, and bulk terminals that can store at least 50,000 barrels of petroleum products or that can receive petroleum products by tanker, barge, or pipeline. Crude oil that is in-transit by water from Alaska, or that is stored on Federal leases or in the Strategic Petroleum Reserve is included. Primary Stocks exclude stocks of foreign origin that are held in bonded warehouse storage. ETBE (Ethyl tertiary butyl ether) (CH3)3COC2H5. An oxygenate blend stock formed by the catalytic etherfication of isobutylene with ethanol. Ethane (C2H6). A normally gaseous straight-chain hydrocarbon. It is a colorless paraffinic gas that boils at a temperature of -127.48 degrees Fahrenheit. It is extracted from natural gas and refinery gas streams. Ether. A generic term applied to a group of organic chemical compounds composed of carbon, hydrogen, and oxygen, characterized by an oxygen atom attached to two carbon atoms (e.g., methyl tertiary butyl ether).

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Ethylene (C2H4). An olefinic hydrocarbon recovered from refinery processes or petrochemical processes. Ethylene is used as a petrochemical feedstock for numerous chemical applications and the production of consumer goods. Exports. Shipments of crude oil and petroleum products from the 50 States and the District of Columbia to foreign countries, Puerto Rico, the Virgin Islands, and other U.S. possessions and territories. Field Production. Represents crude oil production on leases, natural gas liquids production at natural gas processing plants, new supply of other hydrocarbons/ oxygenates and motor gasoline blending components, and fuel ethanol blended into finished motor gasoline. Flexicoking. A thermal cracking process which converts heavy hydrocarbons such as crude oil, tar sands bitumen, and distillation residues into light hydrocarbons. Feedstocks can be any pumpable hydrocarbons including those containing high concentrations of sulfur and metals. Fluid Coking. A thermal cracking process utilizing the fluidized-solids technique to remove carbon (coke) for continuous conversion of heavy, low-grade oils into lighter products. Fresh Feed Input. Represents input of material (crude oil, unfinished oils, natural gas liquids, other hydrocarbons and oxygenates or finished products) to processing units at a refinery that is being processed (input) into a particular unit for the first time. Examples:

(1) Unfinished oils coming out of a crude oil distillation unit which are input into a catalytic cracking unit are considered fresh feed to the catalytic cracking unit. (2) Unfinished oils coming out of a catalytic cracking unit being looped back into the same catalytic cracking unit to be reprocessed are not considered fresh feed.

Fuel Ethanol (C2H5OH). An anhydrous denatured aliphatic alcohol intended for gasoline blending as described in Oxygenates definition. Fuels Solvent Deasphalting. A refining process for removing asphalt compounds from petroleum fractions, such as reduced crude oil. The recovered stream from this process is used to produce fuel products. Gas Oil. A liquid petroleum distillate having a viscosity intermediate between that of kerosene

and lubricating oil. It derives its name from having originally been used in the manufacture of illuminating gas. It is now used to produce distillate fuel oils and gasoline. Gasohol. A blend of finished motor gasoline containing alcohol (generally ethanol but sometimes methanol) at a concentration of 10 percent or less by volume. Data on gasohol that has at least 2.7 percent oxygen, by weight, and is intended for sale inside carbon monoxide nonattainment areas are included in data on oxygenated gasoline. See Oxygenates. Gasoline Blending Components. Naphthas which will be used for blending or compounding into finished aviation or motor gasoline (e.g., straight-run gasoline, alkylate, reformate, benzene, toluene, and xylenes). Excludes oxygenates (alcohols, ethers), butane, and natural gasoline. Gross Input to Atmospheric Crude Oil Distillation Units. Total input to atmospheric crude oil distillation units. Includes all crude oil, lease condensate, natural gas plant liquids, unfinished oils, liquefied refinery gases, slop oils, and other liquid hydrocarbons produced from tar sands, gilsonite, and oil shale. Heavy Gas Oil. Petroleum distillates with an approximate boiling range from 651 degrees Fahrenheit to 1000 degrees Fahrenheit. Hydrogen. The lightest of all gases, occurring chiefly in combination with oxygen in water; exists also in acids, bases, alcohols, petroleum, and other hydrocarbons. Idle Capacity. The component of operable capacity that is not in operation and not under active repair, but capable of being placed in operation within 30 days; and capacity not in operation but under active repair that can be completed within 90 days. Imported Crude Oil Burned As Fuel. The amount of foreign crude oil burned as a fuel oil, usually as residual fuel oil, without being processed as such. Imported crude oil burned as fuel includes lease condensate and liquid hydrocarbons produced from tar sands, gilsonite, and oil shale. Imports. Receipts of crude oil and petroleum products into the 50 States and the District of Columbia from foreign countries, Puerto Rico, the Virgin Islands, and other U.S. possessions and territories.

Isobutane (C4H10). A normally gaseous branch-chain hydrocarbon. It is a colorless paraffinic gas that boils at a temperature of 10.9 degrees

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Fahrenheit. It is extracted from natural gas or refinery gas streams. Isobutylene (C4H8). An olefinic hydrocarbon recovered from refinery processes or petrochemical processes. Isohexane (C6H14). A saturated branch-chain hydrocarbon. It is a colorless liquid that boils at a temperature of 156.2 degrees Fahrenheit. Isomerization. A refining process which alters the fundamental arrangement of atoms in the molecule without adding or removing anything from the original material. Used to convert normal butane into isobutane (C4), an alkylation process feedstock, and normal pentane and hexane into isopentane (C5) and isohexane (C6), high-octane gasoline components. Isopentane. See Natural Gasoline Kerosene. A light petroleum distillate that is used in space heaters, cook stoves, and water heaters and is suitable for use as a light source when burned in wick-fed lamps. Kerosene has a maximum distillation temperature of 400 degrees Fahrenheit at the 10-percent recovery point, a final boiling point of 572 degrees Fahrenheit, and a minimum flash point of 100 degrees Fahrenheit. Included are No. 1-K and No. 2-K, the two grades recognized by ASTM Specification D 3699 as well as all other grades of kerosene called range or stove oil, which have properties similar to those of No. 1 fuel oil. See Kerosene-Type Jet Fuel. Kerosene-Type Jet Fuel. A kerosene-based product having a maximum distillation temperature of 400 degrees Fahrenheit at the 10-percent recovery point and a final maximum boiling point of 572 degrees Fahrenheit and meeting ASTM Specification D 1655 and Military Specifications MIL-T-5624P and MIL-T-83133D (Grades JP-5 and JP-8). It is used for commercial and military turbojet and turboprop aircraft engines.

Commercial. Kerosene-type jet fuel intended for use in commercial aircraft. Military. Kerosene-type jet fuel intended for use in military aircraft.

Lease Condensate. A mixture consisting primarily of pentanes and heavier hydrocarbons which is recovered as a liquid from natural gas in lease separation facilities. This category excludes natural gas liquids, such as butane and propane, which are recovered at downstream natural gas processing plants or facilities. See Natural Gas Liquids. Light Gas Oils. Liquid petroleum distillates heavier than naphtha, with an approximate boiling range

from 401 degrees Fahrenheit to 650 degrees Fahrenheit. Liquefied Petroleum Gases (LPG). A group of hydrocarbon-based gases derived from crude oil refining or nautral gas fractionation. They include: ethane, ethylene, propane, propylene, normal butane, butylenes, isobutane, and isobutylene. For convenience of transportation, these gases are liquefied through pressurization. Liquefied Refinery Gases (LRG). Liquefied petroleum gases fractionated from refinery or still gases. Through compression and/or refrigeration, they are retained in the liquid state. The reported categories are ethane/ethylene, propane/propylene, normal butane/butylenes, and isobutane/isobutylene. Excludes still gas. Lubricants. Substances used to reduce friction between bearing surfaces or as process materials either incorporated into other materials used as processing aids in the manufacture of other products, or used as carriers of other materials. Petroleum lubricants may be produced either from distillates or residues. Lubricants include all grades of lubricating oils from spindle oil to cylinder oil and those used in greases. Merchant Oxygenate Plants. Oxygenate production facilities that are not associated with a petroleum refinery. Production from these facilities is sold under contract or on the spot market to refiners or other gasoline blenders. Methanol (CH3OH). A light, volatile alcohol intended for gasoline blending as described in Oxygenate definition. Middle Distillates. A general classification of refined petroleum products that includes distillate fuel oil and kerosene. Military Kerosene-Type Jet Fuel. See Kerosene-

Type Jet Fuel.

Miscellaneous Products. Includes all finished products not classified elsewhere (e.g., petrolatum, lube refining byproducts (aromatic extracts and tars), absorption oils, ram-jet fuel, petroleum rocket fuels, synthetic natural gas feedstocks, and specialty oils). Note: Beginning with January 2004 data, naphtha-type jet fuel is included in Miscellaneous Products. Motor Gasoline (Finished). A complex mixture of relatively volatile hydrocarbons with or without small quantities of additives, blended to form a fuel suitable for use in spark-ignition engines. Motor gasoline, as defined in ASTM Specification D 4814 or Federal Specification VV-G-1690C, is characterized as having a boiling range of 122 to 158 degrees Fahrenheit at the 10 percent recovery

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point to 365 to 374 degrees Fahrenheit at the 90 percent recovery point. “Motor Gasoline” includes conventional gasoline; all types of oxygenated gasoline, including gasohol; and reformulated gasoline, but excludes aviation gasoline. Note: Volumetric data on blending components, such as oxygenates, are not counted in data on finished motor gasoline until the blending components are blended into the gasoline. Conventional Gasoline. Finished motor gasoline not included in the oxygenated or reformulated gasoline categories. Note: This category excludes reformulated gasoline blendstock for oxygenate blending (RBOB) as well as other blendstock. OPRG. “Oxygenated Fuels Program Reformulated Gasoline” is reformulated gasoline which is intended for use in an oxygenated fuels program control area. Oxygenated Gasoline (Including Gasohol). Oxygenated gasoline includes all finished motor gasoline, other than reformulated gasoline, having oxygen content of 2.0 percent or higher by weight. Gasohol containing a minimum 5.7 percent ethanol by volume is included in oxygenated gasoline. Oxygenated gasoline was reported as a separate product from January 1993 until December 2003 inclusive. Beginning with monthly data for January 2004, oxygenated gasoline is included in conventional gasoline. Historical data for oxygenated gasoline excluded Federal Oxygenated Program Reformulated Gasoline (OPRG). Historical oxygenated gasoline data also excluded other reformulated gasoline with a seasonal oxygen requirement regardless of season. Reformulated Gasoline. Finished gasoline formulated for use in motor vehicles, the composition and properties of which meet the requirements of the reformulated gasoline regulations promulgated by the U.S. Environmental Protection Agency under Section 211(k) of the Clean Air Act. It includes gasoline produced to meet or exceed emissions performance and benzene content standards of federal-program reformulated gasoline even though the gasoline may not meet all of the composition requirements (e.g. oxygen content) of federal-program reformulated gasoline. Reformulated gasoline excludes Reformulated Blendstock for Oxygenate Blending (RBOB) and Gasoline Treated as Blendstock (GTAB). Historical reformulated gasoline statistics included Oxygenated Fuels Program Reformulated Gasoline (OPRG).

Reformulated (Blended with Ether). Reformulated gasoline blended with an ether component (e.g. methyl tertiary butyl ether) at a terminal or refinery to raise the oxygen content.

Reformulated (Blended with Alcohol). Reformulated gasoline blended with an alcohol component (e.g. fuel ethanol) at a terminal or refinery to raise the oxygen content. Reformulated (Non-Oxygenated). Reformulated gasoline without added ether or alcohol components.

Motor Gasoline Blending. Mechanical mixing of motor gasoline blending components, and oxygenates when required, to produce finished motor gasoline. Finished motor gasoline may be further mixed with other motor gasoline blending components or oxygenates, resulting in increased volumes of finished motor gasoline and/or changes in the formulation of finished motor gasoline (e.g., conventional motor gasoline mixed with MTBE to produce oxygenated motor gasoline). Motor Gasoline Blending Components. Naphthas (e.g., straight-run gasoline, alkylate, reformate, benzene, toluene, xylenes) used for blending or compounding into finished motor gasoline. These components include reformulated gasoline blendstock for oxygenate blending (RBOB) but exclude oxygenates (alcohols, ethers), butane, and pentanes. Note: Oxygenates are reported as individual components and are included in the total for other hydrocarbons and oxygenates.

Conventional Blendstock for Oxygenate Blending (CBOB). Conventional gasoline blendstock intended for blending with oxygenates downstream of the refinery where it was produced. CBOB must become conventional gasoline after blending with oxygenates. Motor gasoline blending components that require blending other than with oxygenates to become finished conventional gasoline are reported as All Other Motor Gasoline Blending Components. Excludes reformulated blendstock for oxygenate blending(RBOB). Gasoline Treated as Blendstock (GTAB). Non-certified Foreign Refinery gasoline classified by an importer as blendstock to be either blended or reclassified with respect to reformulated or conventional gasoline. GTAB is classified as either reformulated or conventional based on emissions performance and the intended end use. Reformulated Blendstock for Oxygenate Blending (RBOB). Specially produced reformulated gasoline blendstock intended for blending with oxygenates downstream of the refinery where it was produced. Includes RBOB used to meet requirements of the Federal reformulated gasoline program and other blendstock intended for blending with oxygenates to produce finished gasoline that meets or exceeds emissions performance requirements of Federal

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reformulated gasoline (e.g. California RBOB and Arizona RBOB). Excludes conventional gasoline blendstocks for oxygenate blending (CBOB).

RBOB for Blending with Ether. Motor gasoline blending components intended to be blended with an ether component (e.g. methyl tertiary butyl ether) at a terminal or refinery to raise the oxygen content.

RBOB for Blending with Alcohol. Motor gasoline blending components intended to be blended with an alcohol component (e.g. fuel ethanol) at a terminal or refinery to raise the oxygen content.

All Other Motor Gasoline Blending Components.

Naphthas (e.g. straight-run gasoline, alkylate, reformate, benzene, toluene, xylenes) used for blending or compounding into finished motor gasoline. Includes receipts and inputs of Gasoline Treated as Blendstock (GTAB). Excludes conventional blendstock for oxygenate blending (CBOB), reformulated blendstock for oxygenate blending, oxygenates (e.g. fuel ethanol and methyl tertiary butyl ether), butane, and natural gasoline.

MTBE (Methyl tertiary butyl ether) (CH3)3COCH3.

An ether intended for gasoline blending as described in Oxygenate definition. Naphtha. A generic term applied to a petroleum fraction with an approximate boiling range between 122 degrees Fahrenheit and 400 degrees Fahrenheit. Naphtha Less Than 401

o F. See Petrochemical

Feedstocks. Naphtha-Type Jet Fuel. A fuel in the heavy naphtha boiling range having an average gravity of 52.8 degrees API, 20 to 90 percent distillation temperatures of 290 degrees to 470 degrees Fahrenheit, and meeting Military Specification MIL-T-5624L (Grade JP-4). It is used primarily for military turbojet and turboprop aircraft engines because it has a lower freeze point than other aviation fuels and meets engine requirements at high altitudes and speeds. Note: Beginning with January 2004 data, naphtha-type jet fuel is included in Miscellaneous Products. Natural Gas. A gaseous mixture of hydrocarbon compounds, the primary one being methane. Natural Gas Field Facility. A field facility designed to process natural gas produced from more than one lease for the purpose of recovering condensate from a stream of natural gas; however, some field facilities are designed to recover

propane, normal butane, natural gasoline, etc., and to control the quality of natural gas to be marketed. Natural Gas Liquids. Those hydrocarbons in natural gas that are separated from the gas as liquids through the process of absorption, condensation, adsorption, or other methods in gas processing or cycling plants. Generally such liquids consist of propane and heavier hydrocarbons and are commonly referred to as lease condensate, natural gasoline, and liquefied petroleum gases. Natural gas liquids include natural gas plant liquids (primarily ethane, propane, butane, and isobutane; see Natural Gas Plant Liquids) and lease condensate (primarily pentanes produced from natural gas at lease separators and field facilities; see Lease Condensate). Natural Gas Plant Liquids. Those hydrocarbons in natural gas that are separated as liquids at natural gas processing plants, fractionating and cycling plants, and, in some instances, field facilities. Lease condensate is excluded. Products obtained include ethane; liquefied petroleum gases (propane, butanes, propane-butane mixtures, ethane-propane mixtures); isopentane; and other small quantities of finished products, such as motor gasoline, special naphthas, jet fuel, kerosene, and distillate fuel oil. Natural Gas Processing Plant. Facilities designed to recover natural gas liquids from a stream of natural gas that may or may not have passed through lease separators and/or field separation facilities. These facilities control the quality of the natural gas to be marketed. Cycling plants are classified as gas processing plants. Natural Gasoline and Isopentane. A mixture of hydrocarbons, mostly pentanes and heavier, extracted from natural gas, that meets vapor pressure, end-point, and other specifications for natural gasoline set by the Gas Processors Association. Includes isopentane which is a saturated branch-chain hydrocarbon, (C5H12), obtained by fractionation of natural gasoline or isomerization of normal pentane. Net Receipts. The difference between total movements into and total movements out of each PAD District by pipeline, tanker, and barge. Normal Butane. See Butane. OPEC. The acronym for the Organization of Petroleum Exporting Countries, that have organized for the purpose of negotiating with oil companies on matters of oil production, prices and future concession rights. Current members are Algeria, Indonesia, Iran, Iraq, Kuwait, Libya, Nigeria, Qatar, Saudi Arabia, United Arab Emirates, and Venezuela. The Neutral Zone between Kuwait and Saudi Arabia is considered part of OPEC. Prior

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to January 1, 1993, Ecuador was a member of OPEC. Prior to January 1995, Gabon was a member of OPEC. Operable Capacity. The amount of capacity that, at the beginning of the period, is in operation; not in operation and not under active repair, but capable of being placed in operation within 30 days; or not in operation but under active repair that can be completed within 90 days. Operable capacity is the sum of the operating and idle capacity and is measured in barrels per calendar day or barrels per stream day. Operating Capacity. The component of operable capacity that is in operation at the beginning of the period. Operable Utilization Rate. Represents the utilization of the atmospheric crude oil distillation units. The rate is calculated by dividing the gross input to these units by the operable refining capacity of the units. Operating Utilization Rate. Represents the utilization of the atmospheric crude oil distillation units. The rate is calculated by dividing the gross input to these units by the operating refining capacity of the units. Other Hydrocarbons. Materials received by a refinery and consumed as a raw material. Includes hydrogen, coal tar derivatives, gilsonite, and natural gas received by the refinery for reforming into hydrogen. Natural gas to be used as fuel is excluded. Other Oils Equal To or Greater Than 401

o F. See

Petrochemical Feedstocks.

Other Oxygenates. Other aliphatic alcohols and aliphatic ethers intended for motor gasoline blending (e.g., isopropyl ether (IPE) or n-propanol). Oxygenated Gasoline. See Motor Gasoline (Finished). Oxygenates. Substances which, when added to gasoline, increase the amount of oxygen in that gasoline blend. Fuel Ethanol, Methyl Tertiary Butyl Ether (MTBE), Ethyl Tertiary Butyl Ether (ETBE), and methanol are common oxygenates.

Fuel Ethanol. Blends of up to 10 percent by volume anhydrous ethanol (200 proof) (commonly referred to as the “gasohol waiver”). Methanol. Blends of methanol and gasoline-grade tertiary butyl alcohol (GTBA) such that the total oxygen content does not exceed 3.5 percent by weight and the ratio of methanol to GTBA is less than or equal to 1. It is also specified that this blended fuel must meet

ASTM volatility specifications (commonly referred to as the “ARCO” waiver). Blends of up to 5.0 percent by volume methanol with a minimum of 2.5 percent by volume cosolvent alcohols having a carbon number of 4 or less (i.e., ethanol, propanol, butanol, and/or GTBA). The total oxygen must not exceed 3.7 percent by weight, and the blend must meet ASTM volatility specifications as well as phase separation and alcohol purity specifications (commonly referred to as the “DuPont” waiver). MTBE (Methyl tertiary butyl ether). Blends up to 15.0 percent by volume MTBE which must meet the ASTM D4814 specifications. Blenders must take precautions that the blends are not used as base gasolines for other oxygenated blends (commonly referred to as the “Sun” waiver).

Pentanes Plus. A mixture of hydrocarbons, mostly pentanes and heavier, extracted from natural gas. Includes isopentane, natural gasoline, and plant condensate. Persian Gulf. The countries that comprise the Persian Gulf are: Bahrain, Iran, Iraq, Kuwait, Qatar, Saudi Arabia, and the United Arab Emirates. Petrochemical Feedstocks. Chemical feedstocks derived from petroleum principally for the manufacture of chemicals, synthetic rubber, and a variety of plastics. The categories reported are “Naphtha Less Than 401° F” and “Other Oils Equal To or Greater Than 401° F.”

Naphtha less Than 401o F. A naphtha with a

boiling range of less than 401 degrees Fahrenheit that is intended for use as a petrochemical feedstock. Other Oils Equal To or Greater Than 401

o F.

Oils with a boiling range equal to or greater than 401 degrees Fahrenheit that are intended for use as a petrochemical feedstock.

Petroleum Administration for Defense (PAD)

Districts. Geographic aggregations of the 50 States and the District of Columbia into five districts by the Petroleum Administration for Defense in 1950. These districts were originally defined during World War II for purposes of administering oil allocation. Petroleum Coke. A residue high in carbon content and low in hydrogen that is the final product of thermal decomposition in the condensation process in cracking. This product is reported as

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marketable coke. The conversion is 5 barrels (of 42 U.S. gallons each) per short ton. Coke from petroleum has a heating value of 6.024 million Btu per barrel.

Marketable Coke. Those grades of coke produced in delayed or fluid cokers which may be recovered as relatively pure carbon. This “green” coke may be sold as is or further purified by calcining.

Catalyst Coke. The only catalytic coke used as a fuel is the coke on catalyst in the FCC process. In other catalytic processes there is coke deposited on catalyst, but it is not regenerated in a way such that the heat of combustion is recovered.

Petroleum Products. Petroleum products are obtained from the processing of crude oil (including lease condensate), natural gas, and other hydrocarbon compounds. Petroleum products include unfinished oils, liquefied petroleum gases, pentanes plus, aviation gasoline, motor gasoline, naphtha-type jet fuel, kerosene-type jet fuel, kerosene, distillate fuel oil, residual fuel oil, petrochemical feedstocks, special naphthas, lubricants, waxes, petroleum coke, asphalt, road oil, still gas, and miscellaneous products. Pipeline (Petroleum). Crude oil and product pipelines used to transport crude oil and petroleum products respectively, (including interstate, intrastate, and intra-company pipelines) within the 50 States and the District of Columbia. Plant Condensate. One of the natural gas liquids, mostly pentanes and heavier hydrocarbons, recovered and separated as liquids at gas inlet separators or scrubbers in processing plants. Processing Gain. The volumetric amount by which total output is greater than input for a given period of time. This difference is due to the processing of crude oil into products which, in total, have a lower specific gravity than the crude oil processed. Processing Loss. The volumetric amount by which total refinery output is less than input for a given period of time. This difference is due to the processing of crude oil into products which, in total, have a higher specific gravity than the crude oil processed. Product Supplied, Crude Oil. Crude oil burned on leases and by pipelines as fuel. Production Capacity. The maximum amount of product that can be produced from processing facilities.

Products Supplied. Approximately represents consumption of petroleum products because it measures the disappearance of these products from primary sources, i.e., refineries, natural gas processing plants, blending plants, pipelines, and bulk terminals. In general, product supplied of each product in any given period is computed as follows: field production, plus refinery production, plus imports, plus unaccounted for crude oil, (plus net receipts when calculated on a PAD District basis), minus stock change, minus crude oil losses, minus refinery inputs, minus exports. Propane (C3H8). A normally gaseous straight-chain hydrocarbon. It is a colorless paraffinic gas that boils at a temperature of -43.67 degrees Fahrenheit. It is extracted from natural gas or refinery gas streams. It includes all products designated in ASTM Specification D1835 and Gas Processors Association Specifications for commercial propane and HD-5 propane. Propylene (C3H6). An olefinic hydrocarbon recovered from refinery processes or petrochemical processes. Propylene (C3H6) (nonfuel use). Propylene that is intended for use in nonfuel applications such as petrochemical manufacturing. Nonfuel use propylene includes chemical-grade propylene, polymer-grade propylene, and trace amounts of propane. Nonfuel use propylene also includes the propylene component of propane/propylene mixes where the propylene will be separated from the mix in a propane/propylene splitting process. Excluded is the propylene component of propane/propylene mixes where the propylene component of the mix is intended for sale into the fuel market. Refinery. An installation that manufactures finished petroleum products from crude oil, unfinished oils, natural gas liquids, other hydrocarbons, and oxygenates. Refinery-Grade Butane. See Butane. Refinery Input, Crude Oil. Total crude oil (domestic plus foreign) input to crude oil distillation units and other refinery processing units (cokers, etc.). Refinery Input, Total. The raw materials and intermediate materials processed at refineries to produce finished petroleum products. They include crude oil, products of natural gas processing plants, unfinished oils, other hydrocarbons and oxygenates, motor gasoline and aviation gasoline blending components and finished petroleum products. Refinery Production. Petroleum products produced at a refinery or blending plant. Published production of these products equals refinery

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production minus refinery input. Negative production will occur when the amount of a product produced during the month is less than the amount of that same product that is reprocessed (input) or reclassified to become another product during the same month. Refinery production of unfinished oils, and motor and aviation gasoline blending components appear on a net basis under refinery input. Refinery Yield. Refinery yield (expressed as a percentage) represents the percent of finished product produced from input of crude oil and net input of unfinished oils. It is calculated by dividing the sum of crude oil and net unfinished input into the individual net production of finished products. Before calculating the yield for finished motor gasoline, the input of natural gas liquids, other hydrocarbons and oxygenates, and net input of motor gasoline blending components must be subtracted from the net production of finished motor gasoline. Before calculating the yield for finished aviation gasoline, input of aviation gasoline blending components must be subtracted from the net production of finished aviation gasoline. Reformulated Gasoline. See Motor Gasoline (Finished).

Residual Fuel Oil. A general classification for the heavier oils, known as No. 5 and No. 6 fuel oils, that remain after the distillate fuel oils and lighter hydrocarbons are distilled away in refinery operations. It conforms to ASTM Specifications D 396 and D 975 and Federal Specification VV-F-815C. No. 5, a residual fuel oil of medium viscosity, is also known as Navy Special and is defined in Military Specification MIL-F-859E, including Amendment 2 (NATO Symbol F-770). It is used in steam-powered vessels in government service and inshore power plants. No. 6 fuel oil includes Bunker C fuel oil and is used for the production of electric power, space heating, vessel bunkering, and various industrial purposes. Residuum. Residue from crude oil after distilling off all but the heaviest components, with a boiling range greater than 1000 degrees Fahrenheit. Road Oil. Any heavy petroleum oil, including residual asphaltic oil used as a dust palliative and surface treatment on roads and highways. It is generally produced in six grades from 0, the most liquid, to 5, the most viscous. Shell Storage Capacity. The design capacity of a petroleum storage tank which is always greater than or equal to working storage capacity. Special Naphthas. All finished products within the naphtha boiling range that are used as paint thinners, cleaners, or solvents. These products are refined to a specified flash point. Special naphthas

include all commercial hexane and cleaning solvents conforming to ASTM Specification D1836 and D484, respectively. Naphthas to be blended or marketed as motor gasoline or aviation gasoline, or that are to be used as petrochemical and synthetic natural gas (SNG) feedstocks are excluded. Steam (Purchased). Steam, purchased for use by a refinery, that was not generated from within the refinery complex. Still Gas (Refinery Gas). Any form or mixture of gases produced in refineries by distillation, cracking, reforming, and other processes. The principal constituents are methane, ethane, ethylene, normal butane, butylenes, propane, propylene, etc. Still gas is used as a refinery fuel and a petrochemical feedstock. The conversion factor is 6 million BTU’s per fuel oil equivalent barrel. Stock Change. The difference between stocks at the beginning of the reporting period and stocks at the end of the reporting period. Note: A negative number indicates a decrease (i.e., a drawdown) in stocks and a positive number indicates an increase (i.e., a buildup) in stocks during the reporting period. Strategic Petroleum Reserve (SPR). Petroleum stocks maintained by the Federal Government for use during periods of major supply interruption. Sulfur. A yellowish nonmetallic element, sometimes known as “brimstone.” It is present at various levels of concentration in many fossil fuels whose combustion releases sulfur compounds that are considered harmful to the environment. Some of the most commonly used fossil fuels are categorized according to their sulfur content, with lower sulfur fuels usually selling at a higher price. Note: No. 2 Distillate fuel is currently reported as having either a 0.05 percent or lower sulfur level for on-highway vehicle use or a greater than 0.05 percent sulfur level for off-highway use, home heating oil, and commercial and industrial uses. This also includes Ultra Low Sulfur Diesel (<15 ppm sulfur). Residual fuel, regardless of use, is classified as having either no more than 1 percent sulfur or greater than 1 percent sulfur. Coal is also classified as being low-sulfur at concentrations of 1 percent or less or high-sulfur at concentrations greater than 1 percent. Supply. The components of petroleum supply are field production, refinery production, imports, and net receipts when calculated on a PAD District basis. TAME (Tertiary amyl methyl ether)

(CH3)2(C2H5)COCH3. An oxygenate blend stock formed by the catalytic etherfication of isoamylene with methanol.

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Tank Farm. An installation used by gathering and trunk pipeline companies, crude oil producers, and terminal operators (except refineries) to store crude oil. Tanker and Barge. Vessels that transport crude oil or petroleum products. Data are reported for movements between PAD Districts; from a PAD District to the Panama Canal; or from the Panama Canal to a PAD District. TBA (Tertiary butyl alcohol) (CH3)3COH. An alcohol primarily used as a chemical feedstock, a solvent or feedstock for isobutylene production for MTBE; produced as a co-product of propylene oxide production or by direct hydration of isobutylene. Thermal Cracking. A refining process in which heat and pressure are used to break down, rearrange, or combine hydrocarbon molecules. Thermal cracking includes gas oil, visbreaking, fluid coking, delayed coking, and other thermal cracking processes (e.g., Flexicoking). See individual categories for definition. Toluene (C6H5CH3). Colorless liquid of the aromatic group of petroleum hydrocarbons, made by the catalytic reforming of petroleum naphthas containing methyl cyclohexane. A high-octane gasoline-blending agent, solvent, and chemical intermediate, base for TNT. Unaccounted for Crude Oil. Represents the arithmetic difference between the calculated supply and the calculated disposition of crude oil. The calculated supply is the sum of crude oil production plus imports minus changes in crude oil stocks. The calculated disposition of crude oil is the sum of crude oil input to refineries, crude oil exports, crude oil burned as fuel, and crude oil losses. Unfinished Oils. All oils requiring further processing, except those requiring only mechanical blending. Unfinished oils are produced by partial

refining of crude oil and include naphthas and lighter oils, kerosene and light gas oils, heavy gas oils, and residuum. Unfractionated Streams. Mixtures of unsegregated natural gas liquid components excluding, those in plant condensate. This product is extracted from natural gas. United States. The United States is defined as the 50 States and the District of Columbia. Vacuum Distillation. Distillation under reduced pressure (less than atmospheric) which lowers the boiling temperature of the liquid being distilled. This technique with its relatively low temperatures prevents cracking or decomposition of the charge stock. Visbreaking. A thermal cracking process in which heavy atmospheric or vacuum-still bottoms are cracked at moderate temperatures to increase production of distillate products and reduce viscosity of the distillation residues. Wax. A solid or semi-solid material consisting of a mixture of hydrocarbons obtained or derived from petroleum fractions, or through a Fischer-Tropsch type process, in which the straight-chained paraffin series predominates. This includes all marketable wax, whether crude or refined, with a congealing point (ASTM D 938) between 100 and 200 degrees Fahrenheit and a maximum oil content (ASTM D 3235) of 50 weight percent. Working Storage Capacity. The difference in volume between the maximum safe fill capacity and the quantity below which pump suction is ineffective (bottoms). Xylenes (C6H4(CH3)2). Colorless liquid of the aromatic group of hydrocarbons made the catalytic reforming of certain naphthenic petroleum fractions. Used as high-octane motor and aviation gasoline blending agents, solvents, chemical intermediates. Isomers are metaxylene, orthoxylene, paraxylene.

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EPA-Enforcement Alert: Flaring and Uncontrolled Sulfur ... · laring is an engineering practice that provides for process equip ... Ensure there is adequate ca