Asphalt (petroleum): Difference between revisions
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The vacuum resid may be used as: a [[heavy fuel oil]] blending stock; for further processing in a [[delayed coker]] to produce hydrocarbon [[gas]]es, [[coker naphtha]], [[coker gas oil]] and [[petroleum coke]]; as a feed stock for processing into lubricating oil; or routed through a de-asphalting process to produce petroleum asphalt. The adjacent diagram depicts a portion of the vacuum resid being routed to use as a heavy fuel oil blending stock and a portion being routed through a de-asphalting process. | The vacuum resid may be used as: a [[heavy fuel oil]] blending stock; for further processing in a [[delayed coker]] to produce hydrocarbon [[gas]]es, [[coker naphtha]], [[coker gas oil]] and [[petroleum coke]]; as a feed stock for processing into lubricating oil; or routed through a de-asphalting process to produce petroleum asphalt. The adjacent diagram depicts a portion of the vacuum resid being routed to use as a heavy fuel oil blending stock and a portion being routed through a de-asphalting process. | ||
There are a number of de-asphalting processes. Perhaps the most common one is known as ''propane de-asphalting'' which uses [[Supercritical fluid|supercritical]] [[propane]] (meaning the propane is at temperature and pressure conditions above its [[critical point]]) as a [[solvent]] to separate the lower-boiling, lower-density hydrocarbon oil molecules from the asphaltene molecules. | There are a number of de-asphalting processes. Perhaps the most common one is known as ''propane de-asphalting'' which uses [[Supercritical fluid|supercritical]] [[propane]] (meaning the propane is at temperature and pressure conditions above its [[critical point]]) as a [[solvent]] to extract and separate the lower-boiling, lower-density hydrocarbon oil molecules from the asphaltene molecules. The extraction occurs in a vertical tower operating at an absolute pressure of about 500 psia (34 atmospheres), a bottom temperature of 105 °F (40 °C) and a top temperature of 140 °F (60 °C). The propane enters the extraction tower at the bottom and travels upward counter-current to the asphalt that enters the tower at the top and flows downward. | ||
The propane solvent in the separated deasphalted oil from the top of the extraction tower is stripped out and recycled for re-use in the extraction tower. The solvent-free, deasphalted oil may then be used as a feedstock component in other petroleum refinery processes such as a [[fluid catalytic cracker]] or a [[hydrocracker]] to produce a gasoline blending component.<ref name=Speight/><ref name=Jones/><ref name=Speight2/><ref name=Parkash>{{cite book|author=Surinder Parkash|title=Refining Processes Handbook|edition=First Edition|publisher=Gulf Publishing|year=2003|id=ISBN 0-7506-7721-X}}</ref> | |||
As shown in the adjacent diagram, an air-blowing process consists of using an air [[compressor]] to blow air through the liquid asphalt at a temperature ranging from 235 to 290 °C and being careful to avoid any [[combustion]] of the asphalt by remaining about 25 °C below the [[flash point]] of the feedstock asphalt. In brief, the asphalt fed into an air-blowing process is [[oxidized]] by the [[oxygen]] in the air. The air-blown product asphalt has a higher temperature softening point than asphalt which has not been air-blown and that is a desirable property for certain uses of petroleum asphalt.<ref name=Speight/><ref name=Jones/><ref name=Speight2/><ref name=Parkash/> | Solvent in the asphalt stream from the bottom of the extraction tower is also stripped from the asphalt stream and recycled for re-use. The solvent-free asphalt may then be marketed as end-product petroleum asphalt. Alternatively, all or some of the asphalt product from the de-asphalter may be processed in an air-blowing process to produce what is known as ''air-blown'' or ''oxidized'' asphalt.<ref name=Speight/><ref name=Jones/><ref name=Speight2/><ref name=Parkash/> | ||
As shown in the adjacent diagram, an air-blowing process consists of using an air [[compressor]] to blow air through the liquid asphalt at a temperature ranging from 235 to 290 °C and being careful to avoid any [[combustion]] of the asphalt by remaining about 25 °C below the [[flash point]] of the feedstock asphalt. In brief, the asphalt fed into an air-blowing process is [[oxidized]] by the [[oxygen]] in the air. The three most important operating variables in the asphalt air-blowing process are the rate of air injection, the system temperature and the amount of time that the asphalt is kept in contact with the air.<ref name=Jones/> | |||
The air-blown product asphalt has a higher temperature softening point than asphalt which has not been air-blown and that is a desirable property for certain uses of petroleum asphalt.<ref name=Speight/><ref name=Jones/><ref name=Speight2/><ref name=Parkash/> | |||
The end-product petroleum asphalt is typically maintained at a temperature of about 150 °C during storage at the petroleum refinery as well as during transportation to the asphalt end-users. | The end-product petroleum asphalt is typically maintained at a temperature of about 150 °C during storage at the petroleum refinery as well as during transportation to the asphalt end-users. |
Revision as of 19:34, 18 February 2009
- For other articles with this same name or an associated name, please see Asphalt (disambiguation)
Petroleum asphalt is a sticky, black and highly viscous liquid or semi-solid that is present in most petroleum crude oils and in some natural deposits. Petroleum crude oil is a complex mixture of a great many different hydrocarbons. Petroleum asphalt is defined as that part of crude oil which is separated from the higher-boiling hydrocarbons in crude oil by precipitation upon the addition of lower-boiling hydrocarbon solvents such as propane, pentane, hexane or heptane. The precipitated material consists of asphaltenes which have an average molecular weight of about (800 - 2500 g/mole)[1][2] and exist in the form of flat sheets of polyaromatic condensed rings with short aliphatic chains.[3]
Over the years, petroleum asphalt has been referred to as bitumen, asphaltum or pitch. The terminology varies from country to country and from individual to individual. Asphalt is often confused with coal tar (or coal pitch) derived from the pyrolosis of coal and which has a different chemical structure than asphalt.
When petroleum asphalt is combined with construction aggregate (sand, gravel, crushed stone, etc.) for use in road construction or paving, it has often been referred to as asphaltic concrete, asphaltic cement, bituminous concrete, blacktop or road tar.
The natural deposits of asphalt (often referred to as tar) include asphaltic lakes such as Bermudez Lake in Venezuela, and Pitch Lake in Trinidad. Other natural deposits include oil sands (often called tar sands) and the two largest deposits of oil sands are such as in Alberta, Canada and the Orinoco Oil Belt area of Venezuela.
History of asphalt
The documented use of naturally occurring asphalt dates back almost to 4000 B.C.:[4][5][6][7]
- 3800 B.C.: Asphalt used for caulking boats made of reeds.
- 3500 B.C.: Asphalt used as cement for jewelry.
- 3000 B.C.: Asphalt used as construction cement by the Sumerians of ancient Mesopotamia (now known as Iraq). Also used to seal a bathing pool or water tank in the city of Mohenjo-Daro in the Indus Valley Civilization located in what is now Pakistan.
- 2500 B.C.: Asphalt and other petroleum oils used in ancient Egypt for embalming mummies. (The Persian word for asphalt is mumiyah which may be related to the English word for mummy).
- 1000 B.C.: Asphalt used for waterproofing by lake dwellers in what is now Switzerland.
- 625 – 650 B.C.: The first recorded use of asphalt as a road-building material was in Babylon during the reigns of King Nabopolassar and his son, King Nebuchadnezzar.
- 500 B.C.: Asphalt mixed with sulfur was used as an incendiary device in the Greek wars. (The word asphalt comes from the Greek word asphaltos, meaning secure in English.)
- 300 B.C. – A.D. 250: Reported occurrences of asphalt and oil seepages in Mesopotamia and the use of liquid asphalt as an illuminant in lamps.
- A.D. 750: First reported use in Italy of asphalt as a coloring material in paintings.
Europeans exploring the Americas discovered natural deposits of asphalt. Writing in 1595, Sir Walter Raleigh described a lake of asphalt on the island of Trinidad, near Venezuela. He used it to recaulk his ships.[5][6]
In the late 1700s and early 1800s, first Pierre-Marie-Jérôme Trésaguet of France, then Thomas Telford and subsequently John Loudon McAdam (both of Scotland) perfected the leveling, draining and construction of roads using layers of broken stones and gravel. In the period of 1860 – 1880, to reduce road dust and road maintenance, builders began using hot coal tar to bond the stones together. Such roads became named after McAdam and known as tarmacadam roads, later shortened to tarmac.[5][6][7][8]
In 1870, Belgian chemist Edmond J. DeSmedt laid the first true asphalt pavement in the United States in Newark, New Jersey. He also paved Pennsylvania Avenue in Washington, D.C. in 1876 using 54,000 square yards (45,140 square metres) of sheet asphalt from Pitch Lake in Trinidad.[5][6]
During the early 1900s, coal gasification was being widely used to produce town gas and the by-product tar produced during coal gasification was a readily available product.[8] That tar was extensively used in the construction of tarmacadam (or, more simply, tarmac) roads.
By 1907, asphalt from petroleum refineries had outstripped the use of natural asphalt from Trinidad or elsewhere.[6]. Later in the 1900s, when natural gas replaced town gas, asphalt from petroleum refineries dominated the asphalt paving market from that point on. By the early 1990s, asphalt paving mixture producers in the United States used more than 50 × 106 barrels (7.95 × 106 cubic metres) of petroleum asphalt per year. Of the 2.27 × 106 miles (3.65 × 106 kilometers) of paved road in the United States, 94 percent of them are surfaced with asphalt, including 65 percent of the interstate system. [9]
Asphalt production from petroleum crude oil
As mentioned earlier above, petroleum crude oil is essentially a complex mixture of a great many hydrocarbons. There are a great many different crude oil sources and each of the crude oils from those sources has its own unique mixture of hydrocarbons. Upon being fed into a petroleum refinery, the crude oil is initially distilled (i.e., boiled) to remove and recover various products such as naphtha which is subsequently further refined to produce gasoline (petrol), jet fuel, diesel oil, heating oil and so-called vacuum oils which may also be further refined to produce more gasoline.[4][10][11][12]
The initial distillation of the petroleum crude oil is done in two steps as shown in the adjacent diagram:
- The first step is atmospheric distillation, at an absolute pressure slightly above atmospheric pressure, after heating the crude oil in a process furnace to a temperature of about 395 °C. That temperature cannot be exceeded because, above that temperature, the hydrocarbon molecules will crack (break) into smaller molecules and coke that is essentially solid carbon which would plug up the furnace tubes.[4][10][11][12]
- The second step is vacuum distillation at an absolute pressure of 10 – 40 mmHg. The temperature must still be limited to being no higher than about 395 °C. However, under the vacuum of 10 – 40 mmHg, that is equivalent to a boiling point of about 565 °C at atmospheric pressure.[4][10][11][12]
The residual bottoms product from the atmospheric distillation is referred to as atmospheric resid or atmospheric residuum. Similarly, the residual bottoms product from the vacuum distillation is referred to as vacuum resid or vacuum residuum. In some refineries that process very heavy crude oils (i.e., crude oil with a higher than average crude oil density), the atmospheric resid may be suitable for further processing to obtain a petroleum asphalt end-product. However, again as shown in the adjacent diagram, it is more generally the vacuum resid that is further processed to derive an end-product of petroleum asphalt.[4][10][11]
The vacuum resid may be used as: a heavy fuel oil blending stock; for further processing in a delayed coker to produce hydrocarbon gases, coker naphtha, coker gas oil and petroleum coke; as a feed stock for processing into lubricating oil; or routed through a de-asphalting process to produce petroleum asphalt. The adjacent diagram depicts a portion of the vacuum resid being routed to use as a heavy fuel oil blending stock and a portion being routed through a de-asphalting process.
There are a number of de-asphalting processes. Perhaps the most common one is known as propane de-asphalting which uses supercritical propane (meaning the propane is at temperature and pressure conditions above its critical point) as a solvent to extract and separate the lower-boiling, lower-density hydrocarbon oil molecules from the asphaltene molecules. The extraction occurs in a vertical tower operating at an absolute pressure of about 500 psia (34 atmospheres), a bottom temperature of 105 °F (40 °C) and a top temperature of 140 °F (60 °C). The propane enters the extraction tower at the bottom and travels upward counter-current to the asphalt that enters the tower at the top and flows downward.
The propane solvent in the separated deasphalted oil from the top of the extraction tower is stripped out and recycled for re-use in the extraction tower. The solvent-free, deasphalted oil may then be used as a feedstock component in other petroleum refinery processes such as a fluid catalytic cracker or a hydrocracker to produce a gasoline blending component.[4][10][11][13]
Solvent in the asphalt stream from the bottom of the extraction tower is also stripped from the asphalt stream and recycled for re-use. The solvent-free asphalt may then be marketed as end-product petroleum asphalt. Alternatively, all or some of the asphalt product from the de-asphalter may be processed in an air-blowing process to produce what is known as air-blown or oxidized asphalt.[4][10][11][13]
As shown in the adjacent diagram, an air-blowing process consists of using an air compressor to blow air through the liquid asphalt at a temperature ranging from 235 to 290 °C and being careful to avoid any combustion of the asphalt by remaining about 25 °C below the flash point of the feedstock asphalt. In brief, the asphalt fed into an air-blowing process is oxidized by the oxygen in the air. The three most important operating variables in the asphalt air-blowing process are the rate of air injection, the system temperature and the amount of time that the asphalt is kept in contact with the air.[10]
The air-blown product asphalt has a higher temperature softening point than asphalt which has not been air-blown and that is a desirable property for certain uses of petroleum asphalt.[4][10][11][13]
The end-product petroleum asphalt is typically maintained at a temperature of about 150 °C during storage at the petroleum refinery as well as during transportation to the asphalt end-users.
Some important physical properties of petroleum asphalt
There are a number of physical properties that are important to the end-users of petroleum asphalt, including:[14]
- Softening Point: The range of temperatures at which the asphalt softens (as determined by ASTM test D-36). The softening point is sometimes thought of as the melting point.
- Penetration: The distance that a weighted needle or cone will sink into the asphalt during a set period of time at a prescribed temperature (as determined by ASTM test D-5). Penetration results are presented in units of 0.1 mm (i.e., the units are given as dmm). Thus, a penetration of 40 means the needle has penetrated 4 mm.
- Viscosity: An indication of how viscous the liquid asphalt is at various temperatures (as determined by ASTM tests D-88 and D-2170).
- Flash Point: The temperature at which that the heated asphalt will ignite briefly (as determined by ASTM test D-92).
The softening point and penetration are the most commonly used measurements for classifying an asphalt's properties. Generally, as the softening point increases, the viscosity also increases, the penetration drops and the flash point rises.
Uses of petroleum asphalt
Road construction
The largest use of petroleum asphalt is for making asphaltic concrete for road construction and accounts for approximately 80% of the petroleum asphalt consumed in the United States. The asphalt is used as the binder or glue that holds together the aggregate of sand, gravel, crushed stone, slag or other material.
There are various mixtures of asphalt with other materials that are used in road construction and other paving applications:
- Rolled asphaltic concrete that contains about 95% aggregate and 5% petroleum asphalt binder.
- Mastic asphalt that contains about 90–93% aggregate and 7–10% petroleum asphalt binder.
- Asphalt emulsions that contain about 70% petroleum asphalt and 30% water plus a small amount of chemical additives.
- Cutback asphalt that contains petroleum solvents (referred to as cutbacks).
Only rarely, if ever, are air-blown asphalts used in asphalt-aggregate mixtures for paving purposes.[15]
Roofing shingles
Roofing shingles account for most of the remaining 20% of asphalt consumption in the United States. Most of the petroleum asphalt used in manufacturing shingles is air-blown asphalt. There are three major grades (types) of asphalt used for roofing:[10]
- Type 1: Penetration at 77 °F (25 °C) = 25 − 50 dmm and softening point of 140 − 150 °F (60 − 66 °C).
- Type 2: Penetration at 77 °F (25 °C) = 20 − 30 dmm and softening point of 166 − 175 °F (74 − 79 °C).
- Type 3: Penetration at 77 °F (25 °C) = 15 − 25 dmm and softening point of 190 − 205 °F (88 − 96 °C).
Asphalt roofing shingles are the dominant roofing material in the United States, representing more than three-fifths of the total installed shingle.[16] They are a very economical roofing choice, especially so for house with sloping roofs.[17]
There are two basic types of asphalt shingles, those with an organic base and those with a fiberglass base:[18]
- Fiberglass shingles have a glass fiber reinforced mat coated with asphalt that contains mineral fillers. The glass fiber mat is not waterproof by itself, but the asphalt coating makes it waterproof.
- Organic base shingles are generally paper saturated with asphalt for waterproofing. Then a top coating of asphalt is applied and ceramic granules are imbedded in that top coating. Organic shingles contain about 40% more asphalt than fiberglass shingles which makes them heavier and more resistant to being blown off in windy conditions.
In hot climate areas, the amount of sunlight reflectance provided by the shingles is an important property in evaluating the performance of a specific brand of shingle. Reflectance is provide by the embedded granules and by colored shingle coatings.[17][19]
According to the U.S. Census Bureau, asphalt shingles accounted for more than half of the residential roofing market during the early 2000s.[20]
Other uses
- Asphaltic concrete is widely used for paving vehicle parking lots and aircraft landing and take-off runways in airports around the world
- Canal and reservoir linings as well as dam facings
- Floor tiles
- Battery casings
- Waterproofing of fabrics and various other materials
- Treatment of fence posts and other wooden objects
- Cattle sprays
Asphalt production from oil sands
Type of project | Number of projects |
bbl/day of asphalt |
---|---|---|
In situ extraction | 12 | 595,000 |
Surface mining | 4 | 1,018,000 |
Upgrading | 3 | 1,002,000 |
Note: 1 bbl/day = 158.987 L/day = 0.159 m3/day |
There are three large natural deposits of asphalt (or bitumen) in Alberta, Canada that are known as the Athabasca oil sands and their total surface area is about 54,000 square miles (141,000 square kilometres).[22] The oil sands consist of about 83% sand, 3% clay, 4% water and 10% asphalt.
The proven reserves of asphalt in those deposits are about 1.7 × 1012 barrels (270 Gm3 ). About 10% of that is recoverable by current (2009) technology and it is estimated that, with new technologies, the recoverable amount could be about 18-19% which would be about 315 × 109 barrels (50 Gm3 ).[21] For comparison, the estimated reserves of petroleum crude oil in Saudi Arabia (as of early 2008) are about 265 × 109 barrels (42 Gm3 ).[23]
Asphalt is currently being extracted from the Athabasca oil sands and being converted into synthetic petroleum crude oil (referred to as syncrude). About 20% of the Athabasca oil sands can be and is being extracted by surface mining techniques. In addition, in situ techniques are being used to extract asphalt from various depths beneath the surface of the oil sands deposits. After extraction, the asphalt is converted into synthetic petroleum crude oil in refining facilities that are referred to as upgraders.[21][24] Currently, about 1,000,000 barrels (159,000 m3 ) of the asphalt are being converted into synthetic crude oil (see adjacent table).
On average, upgrading of about 1.16 barrels of asphalt is required to produce 1 barrel of syncrude.[24][25] The synthetic crude oil is subsequently transported to conventional petroleum refineries for processing.
Very little, if any, of the extracted asphalt is used for road construction because the Athabasca oil sands are far from the major markets for road construction asphalt and the transportation costs would be too high.
References
- ↑ Oliver Mullins and Eric Sheu (Editors) (1999). Structure & Dynamics of Asphaltenes, 1st Edition. Springer. ISBN 0-306-45930-2. (See Chapter 1, page 17)
- ↑ Note: There are many other values in the technical literature for the molecular weight of asphaltenes and there does not appear to be a concensus as to which values are more correct.
- ↑ Experimental Investigation of Asphaltene Precipitation From website of the Research Institute of Petroleum Industry in Tehran, Iran.
- ↑ 4.0 4.1 4.2 4.3 4.4 4.5 4.6 4.7 James G. Speight and Baki Ozum (2002). Petroleum Refining Processes. Marcel Dekker. ISBN 0-8247-0599-8.
- ↑ 5.0 5.1 5.2 5.3 The History of Asphalt From the website of beyondRoads.com.
- ↑ 6.0 6.1 6.2 6.3 6.4 History of Asphalt From the website of the National Asphalt Pavement Association.
- ↑ 7.0 7.1 Online Etymology Dictionary by Douglas Harper
- ↑ 8.0 8.1 Maxwell G. Lay (1999). Handbook of Road Technology, 3rd edition. Taylor&Francis. ISBN 90-5699-157-4.
- ↑ SIC 2951, Asphalt Paving Mixtures and Blocks
- ↑ 10.0 10.1 10.2 10.3 10.4 10.5 10.6 10.7 10.8 David S.J. Jones and Peter P.Pujado (Editors) (2006). Handbook of Petroleum Processing, First Edition. Springer. ISBN 1-4020-2819-9.
- ↑ 11.0 11.1 11.2 11.3 11.4 11.5 11.6 James G. Speight, Sunggyu Lee and Sudarshan K. Loyalka (2007). Handbook of Alternative Fuel Technologies, 1st Edition. CRC Press. ISBN 0-8247-4069-6.
- ↑ 12.0 12.1 12.2 Gary, J.H. and Handwerk, G.E. (1984). Petroleum Refining Technology and Economics, 2nd Edition. Marcel Dekker, Inc. ISBN 0-8247-7150-8.
- ↑ 13.0 13.1 13.2 Surinder Parkash (2003). Refining Processes Handbook, First Edition. Gulf Publishing. ISBN 0-7506-7721-X.
- ↑ Specialty Asphalt
- ↑ Air-blown Asphalt: Pilot Plant
- ↑ Research Studies: Freedonia Group, February 2003
- ↑ 17.0 17.1 Asphalt shingles
- ↑ Types of Asphalt Shingles
- ↑ Cool Roofs for Hot Climates
- ↑ NAICS CODE 324122: Asphalt Shingle and Coating Materials Manufacturing
- ↑ 21.0 21.1 21.2 Alberta Oil Sands Industry, Quarterly Update, February 2, 2009
- ↑ Canada's Oil Sands a website of the Canadian Association of Petroleum Producers (CAPP).
- ↑ Oil& Gas Journal, December 24, 2007
- ↑ 24.0 24.1 Unconventional Oil: Tar Sands and Shale Oil Part 3 of 6 parts of a series entitled Energy Return on Investment (EROI) on the Web contributed by Professor Charles Hall of the State University of New York (SUNY) and his students (of whom, the authors of this Part 3 were M.C. Herweyer and A. Gupta)
- ↑ Nonconventional Liquid fuels From a U.S. Department of Energy website.