System, apparatus and process for extraction of bitumen from oil sands
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01D-021/26
출원번호
US-0938226
(2007-11-09)
등록번호
US-8225944
(2012-07-24)
우선권정보
CA-2526336 (2005-11-09)
발명자
/ 주소
Bjornson, Bradford E.
Strand, Craig Aaron
Garner, William Nicholas
Diep, John Khai-Quang
Kiel, Darwin Edward
Hann, Thomas Charles
출원인 / 주소
Suncor Energy Inc.
대리인 / 주소
Knobbe, Martens, Olson & Bear, LLP
인용정보
피인용 횟수 :
4인용 특허 :
86
초록▼
An extraction system and process for extracting bitumen from a slurry containing bitumen, solids and water. The system comprises a cyclone separation facility for separating the slurry into a solids component stream and a bitumen froth stream with the bitumen froth stream including water and fine so
An extraction system and process for extracting bitumen from a slurry containing bitumen, solids and water. The system comprises a cyclone separation facility for separating the slurry into a solids component stream and a bitumen froth stream with the bitumen froth stream including water and fine solids. The bitumen froth stream is then delivered to a froth concentration facility for separating the bitumen froth stream into a final bitumen enriched froth stream, and a water and fine solids stream. The final bitumen enriched froth stream is suitable for further processing. The system of the present invention is preferably mobile so that the cyclone extraction facility and the froth concentration facility can move with the mine face at an oil sands mining site, however, it is also contemplated that the system can be retrofitted to existing fixed treatment facilities to improve the operational efficiency of such fixed facilities.
대표청구항▼
1. A concentrator vessel for separating a bitumen froth stream containing bitumen froth, water and fine solids into a final bitumen enriched froth stream and a water and fine solids stream, the concentrator vessel comprising: an inlet region to receive the bitumen froth stream and distribute the bit
1. A concentrator vessel for separating a bitumen froth stream containing bitumen froth, water and fine solids into a final bitumen enriched froth stream and a water and fine solids stream, the concentrator vessel comprising: an inlet region to receive the bitumen froth stream and distribute the bitumen froth stream as a substantially balanced flow across a separation region;the separation region being adapted to establish uniform, substantially horizontal flow of the bitumen froth stream to promote separation of the bitumen froth from the water and fine solids, the bitumen froth tending to move upwardly to accumulate as a froth layer atop a water layer with the fine solids settling within the water layer;a froth recovery region in communication with the separation region having an overflow outlet to collect the bitumen froth layer as the bitumen enriched froth stream;an underflow outlet configured to collect the water and fine solids as the water and fine solids stream; anda flow level control device configured to control the level of the water layer within the vessel to permit the overflow outlet to collect the bitumen froth layer despite variations in the volume of the bitumen froth stream. 2. The vessel of claim 1 in which the flow level control device comprises a flow control weir adjacent the froth recovery region. 3. The vessel of claim 2 in which the flow level control device is a serpentine weir. 4. The vessel of claim 1 in which the flow level control device is a pump. 5. The vessel of claim 1 in which the flow level control device is a valve. 6. The vessel of claim 1 including conditioning means to promote a substantially uniform velocity flow of the bitumen froth stream. 7. The vessel of claim 6 in which the conditioning means comprises an enclosure to isolate the bitumen froth stream entering the vessel at the inlet region from the separation region to avoid generation of turbulence in the separation region, the bitumen froth stream exiting the enclosure through a perforated member. 8. The vessel of claim 6 in which the conditioning means comprises a diverging channel. 9. The vessel of claim 6 in which the conditioning means comprises at least one channel for directing the flow of the bitumen froth stream. 10. The vessel of claim 6 in which the conditioning means comprises a change in elevation in the vessel adapted to create a hydraulic jump in the bitumen froth stream. 11. The vessel of claim 6 in which the conditioning means comprises at least one channel that includes at least one turn to increase the length of the channel. 12. The vessel of claim 1 in which the inlet region is positioned above the separation and froth recovery regions. 13. The vessel of claim 1 in which the overflow outlet comprises at least one outlet weir positioned in the froth recovery region. 14. The vessel of claim 13, in which the at least one outlet weir comprises a channel having a J-shaped cross-section. 15. The vessel of claim 1 in which the overflow outlet communicates with a froth launder that collects the final bitumen froth stream. 16. The vessel of claim 15 in which the froth launder extends about the perimeter of the froth recovery region. 17. The vessel of claim 1 in which at least the separation region and the froth recovery region include a sloped floor angled to promote flow from the inlet region to the overflow and underflow outlets. 18. The vessel of claim 17 in which the sloped floor is inclined at an angle in the range of 3 to 7%. 19. The vessel of claim 1 including a fine solids outlet for discharging fine solids collected in the vessel. 20. The vessel of claim 2 in which the flow control weir is positioned upstream of the underflow outlet. 21. The vessel of claim 1 in which the separation region includes at least one turn to increase the length of the separation region. 22. The vessel of claim 21 in which the inlet region communicates with a flow volume enclosed by an outer perimeter wall and a floor, the separation region being defined by at least one barrier within the outer perimeter wall, the at least one barrier terminating a distance from the outer perimeter wall to form the at least one turn in the separation region, and the froth recovery region being adjacent the outer perimeter wall of the flow volume. 23. The vessel of claim 22 in which the at least one barrier comprises a pair of diverging barriers adjacent the inlet region to form the separation region as a diverging channel centrally within the flow volume, each barrier terminating a distance from the perimeter wall to form the at least one turn in the channel whereby the diverging channel divides into two diverging channels formed at opposite sides of the flow volume between each barrier and the outer perimeter wall adjacent the barrier. 24. The vessel of claim 23 including a central wall between the pair of diverging barriers to form a pair of diverging channels adjacent the inlet region. 25. The vessel of claim 22 including flow re-direction means to promote smooth flow through the at least one turn. 26. The vessel of claim 25 in which the flow re-direction means comprise vanes adapted to re-direct the flow through the at least one turn. 27. The vessel of claim 25 in which the flow re-direction means comprises rounded corners formed in the outer perimeter walls of the flow volume. 28. The vessel of claim 21 in which the at least one turn is through substantially 180 degrees. 29. The vessel of claim 1 in which the vessel includes froth layer flow enhancement means to prevent formation of stagnant regions in the froth layer. 30. The vessel of claim 29 in which the froth layer flow enhancement means comprises a rotatable paddle element. 31. An extraction system for extracting bitumen from a slurry containing bitumen, solids and water comprising: a cyclone separation facility for separating the slurry into a solids component stream and a bitumen froth stream, the bitumen froth stream including bitumen froth, water and fine solids; anda froth concentration facility for separating the bitumen froth stream into a final bitumen enriched froth stream, and a water and fine solids stream, the froth concentration facility comprising the concentrator vessel of claim 1. 32. The system of claim 31 in which the slurry is delivered to the cyclone separation facility by a hydro-transport pipeline. 33. The system of claim 31 wherein the cyclone separation facility comprises at least one cyclone separation stage. 34. The system of claim 33 wherein the cyclone separation facility comprises at least two cyclone separation stages arranged in a counter-current flow configuration with the slurry being fed to an upstream stage and water being fed to a downstream stage. 35. The system of claim 33 in which the cyclone separation facility comprises a mobile cyclone separation facility. 36. The system of claim 35 in which each cyclone separation stage of the cyclone separation facility comprises a mobile module, the mobile modules being combinable to form the mobile cyclone separation facility. 37. The system of claim 31 in which the froth concentration facility further comprises at least one device selected from the group consisting of a flotation column, a horizontal decanter, a separation cell, and an inclined plate separator. 38. The system of claim 31 wherein the froth concentration facility comprises a mobile froth concentration facility. 39. The system of claim 38 in which the system comprises a plurality of concentrator vessels, and each concentrator vessel is a mobile module, the mobile modules being combinable to form the mobile froth concentration facility. 40. The system of claim 38 in which the froth concentration facility is movable independently of the cyclone separation facility. 41. The system of claim 31 wherein the cyclone separation facility and the froth concentration facility are mobile as a single unit. 42. The system of claim 31 in which the inlet region includes conditioning means to promote a uniform velocity flow of the froth stream as the stream enters the separation region. 43. The system of claim 42 in which the conditioning means comprise an enclosure to isolate the bitumen froth stream entering the vessel at the inlet region from the separation region to minimize turbulence intensities in the separation region, the bitumen froth stream exiting the enclosure through a baffle plate to establish the uniform velocity flow. 44. The system of claim 31 in which the separation region includes at least one turn to increase the length of the separation region. 45. The system of claim 44 in which the inlet region communicates with a flow volume enclosed by an outer perimeter wall and a floor, the separation region being defined by at least one barrier within the outer perimeter wall, the at least one barrier terminating a distance from the outer perimeter wall to form the at least one turn in the separation region, and the froth recovery region being adjacent the outer perimeter wall of the flow volume. 46. The system of claim 45 in which the at least one barrier comprises a pair of diverging barriers adjacent the inlet region to form the separation region as a diverging channel centrally within the flow volume, each barrier terminating a distance from the perimeter wall to form the at least one turn in the channel whereby the diverging channel divides into two diverging channels formed at opposite sides of the flow volume between each barrier and the outer perimeter wall adjacent the barrier. 47. The system of claim 46 including a central wall between the pair of diverging barriers to form a pair of diverging channels adjacent the inlet region. 48. The system of claim 44 including flow re-direction means to promote smooth flow through the at least one turn. 49. The system of claim 48 in which the flow re-direction means comprise vanes adapted to re-direct the flow through the at least one turn. 50. The system of claim 48 in which the flow re-direction means comprises rounded corners formed in the outer perimeter walls of the flow volume. 51. The system of claim 44 in which the at least one turn is through substantially 180 degrees. 52. The system of claim 31 in which the concentrator vessel includes froth layer flow enhancement means to prevent formation of stagnant regions in the froth layer. 53. The system of claim 52 in which the froth layer flow enhancement means comprises a rotatable paddle element. 54. The system of claim 31 in which the overflow outlet comprises at least one weir formed at a perimeter of the froth recovery region. 55. The system of claim 54 in which the at least one weir comprises a J weir. 56. The system of claim 54 in which the overflow outlet communicates with a froth launder that collects the final bitumen enriched froth stream. 57. The system of claim 56 in which the froth launder extends about the perimeter of the froth recovery region. 58. The system of claim 31 in which at least the separation region and the froth recovery region include a floor inclined to create flow from the inlet region to the overflow and underflow outlets. 59. The system of claim 56 including a weir adapted to permit any bitumen froth that exits the underflow outlet to overflow into the froth launder. 60. The system of claim 31 further comprising a water recovery facility for separating the water and fine solids stream from the froth concentration facility into a water stream and a fine solids stream. 61. The system of claim 60 wherein the water stream from the water recovery facility is recycled to the cyclone separation facility. 62. The system of claim 61 wherein the water recovery facility comprises at least one water separation unit selected from the group consisting of a cyclone stage and a thickener. 63. The system of claim 60 in which the water recovery facility is a mobile facility. 64. The system of claim 31 further comprising a scalping unit to remove bitumen rich froth from the slurry prior to entering the cyclone separation facility. 65. The system of claim 31 further comprising a screening and comminuting unit to screen and re-size solids particles from the slurry that exceed a pre-determined size prior to entering the cyclone separation facility.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (86)
Miller Jan D. (Salt Lake City UT) Yi Ye (Salt Lake City UT), Air sparged hydrocyclone flotation apparatus and methods for separating particles from a particulate suspension.
Holmes Jeffrey W. (Sedro-Woolley WA) Purcell Bruce K. (Baton Rouge LA) Franz William F. (Cardiner NY) Cole Edward L. (Fishkill NY), Apparatus for sulfuric acid catalyzed alkylation process.
Franz William F. (Cardiner NY) Cole Edward L. (Fishkill NY), Isoparaffin-olefin alkylation utilizing a continuous sulfuric acid phase in a tubular reaction zone.
Carroll Noel (Sassafras CA AUX) Carroll Robert W. (Bradbury CA) Kalnins Charles M. (Malvern AUX), Method and apparatus for maintaining predetermined cyclone separation efficiency.
Graham Robert J. (Naperville IL) Helstrom John J. (Naperville IL) Peck Lawrence B. (Houston TX) Stone Richard A. (Yorkville IL) Bernier ; Jr. Edward J. (Naperville IL), Methods of tar sand bitumen recovery.
Cymerman George J. (Edmonton CAX) Leung Antony H. S. (Sherwood Park CAX) Maciejewski Waldemar B. (Edmonton CAX), Pipeline conditioning process for mined oil-sand.
Tipman Robert N. (Sherwood Park CAX) Rajan Varagur S. V. (Sherwood Park CAX) Wallace Dean (Beaumont CAX), Process for increasing the bitumen content of oil sands froth.
Hanson Francis V. (Salt Lake City UT) Miller Jan D. (Salt Lake City UT) Oblad Alex G. (Salt Lake City UT), Process for obtaining products from tar sand.
Gardner ; Jr. Homer K. (Metairie LA) Hron ; Sr. Robert J. (New Orleans LA) Vix Henry L. E. (Metairie LA) Ridlehuber Jim M. (Lubbock TX), Process for producing an edible cottonseed protein concentrate.
Gregoli Armand A. (Tulsa OK) Hamshar ; 3rd John A. (Owasso OK) Rimmer Daniel P. (Broken Arrow OK) Yildirim Erdal (Calgary OH CAX) Olah Andrew M. (Spencer OH), Process for recovery of hydrocarbons and rejection of sand.
Gregoli Armand A. (Tulsa OK) Hamshar John A. (Owasso OK) Rimmer Daniel P. (Broken Arrow OK) Yildirim Erdal (Calgary CAX), Process for recovery of hydrocarbons and rejection of sand.
Shelfantook William E. (#1 ; 11115-27 Avenue Edmonton ; Alberta ; T6J 5H3 CAX) Hyndman Alexander W. (168 Brosseau Crescent Fort McMurray ; Alberta ; T9K 1T2 CAX) Hackman Larry P. (16 ; Flint Crescent, Purification process for bitumen froth.
Jansen Wayne B. (Edmonton CAX) Thompson Gordon R. (Edmonton CAX) Dougan Patrick D. (Sherwood Park CAX) Betts Malcolm S. (Fort McMurray CAX) Larson Gordon R. (Fort McMurray CAX), Reducing the water and solids contents of bitumen froth moving through the launder of a spontaneous flotation vessel.
Volchek Konstantin (Burlington CAX) Mortazavi Saviz (Nepean CAX) Whittaker Harry (Manotick CAX), Removal of arsenic from aqueous liquids with selected alumina.
Shaw Christopher K. (Houston TX) Tuckett Phillip C. (Berwick TX AUX) Bowers Bill E. (The Woodlands TX), System and process for hydrocyclone separation of particulate solids and at least one liquid phase from a multiphase liq.
Cymbalisty, Lubomyr M. O.; Cymerman, George J., Treatment of primary tailings and middlings from the hot water extraction process for recovering bitumen from tar sand.
Bjornson, Bradford E.; Strand, Craig Aaron; Garner, William Nicholas; Diep, John Khai-Quang; Kiel, Darwin Edward; Hann, Thomas Charles, System, apparatus and process for extraction of bitumen from oil sands.
Bjornson, Bradford E.; Strand, Craig Aaron; Garner, William Nicholas; Diep, John Khai-Quang; Kiel, Darwin Edward; Hann, Thomas Charles, System, apparatus and process for extraction of bitumen from oil sands.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.