System, apparatus and process for extraction of bitumen from oil sands
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B01D-021/06
B01D-021/24
B01D-021/34
C02F-001/34
C02F-001/38
B01D-021/26
출원번호
US-0329177
(2011-12-16)
등록번호
US-8800784
(2014-08-12)
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 :
0인용 특허 :
89
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;a separation region in
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;a separation region in communication with the inlet region comprising a diverging channel adapted to slow the flow of the bitumen froth stream to promote separation of the bitumen froth from the water and fine solids, the bitumen froth accumulating as a froth layer atop a water layer with the fine solids settling within the water layer; anda froth recovery region in communication with the separation region having an overflow outlet to collect the bitumen froth layer as the final bitumen enriched froth stream, wherein the overflow outlet: (a) comprises at least one weir formed at a perimeter of the froth recovery region; and(b) communicates with a froth launder that collects the final bitumen froth stream; andan underflow outlet configured to collect the water and fine solids as the water and fine solids stream. 2. The vessel of claim 1 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. 3. The vessel of claim 2 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 avoid generation of turbulence in the separation region, the bitumen froth stream exiting the enclosure through a baffle plate to establish the uniform velocity flow. 4. The vessel of claim 1 in which the diverging channel includes at least one turn to increase the length of the channel. 5. The vessel of claim 4 in which the inlet region communicates with a flow volume enclosed by an outer perimeter wall and a floor, the diverging channel 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 channel, and the froth recovery region being adjacent the outer perimeter wall of the flow volume. 6. The vessel of claim 5 in which the at least one barrier comprises a pair of diverging barriers adjacent the inlet region to form the 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. 7. The vessel of claim 6 including a central wall between the pair of diverging barriers to form a pair of diverging channels adjacent the inlet region. 8. The vessel of claim 4 including flow re-direction means to promote smooth flow through the at least one turn. 9. The vessel of claim 8 in which the flow re-direction means comprise vanes adapted to re-direct the flow through the at least one turn. 10. The vessel of claim 8 in which the flow re-direction means comprises rounded corners formed in the outer perimeter walls of the flow volume. 11. The vessel of claim 4 in which the at least one turn is through substantially 180 degrees. 12. The vessel of claim 1 including froth layer flow enhancement means to prevent formation of stagnant regions in the froth layer. 13. The vessel of claim 12 in which the froth layer flow enhancement means comprises a rotatable paddle element. 14. The vessel of claim 1 in which the at least one weir comprises a J weir. 15. The vessel of claim 1 in which the froth launder extends about the perimeter of the froth recovery region. 16. The vessel of claim 1 in which at least the separation region and the froth recovery region include a floor inclined to create flow from the inlet to the overflow and underflow outlets. 17. The vessel of claim 1 including a weir adapted to permit any bitumen froth that exits the underflow outlet to overflow into the froth launder. 18. The vessel of claim 1 wherein the diverging channel comprises first and second walls spaced apart in a horizontal reference plane by a first width in an upstream portion of the separation region and spaced apart in the horizontal reference plane by a second width, wider than the first width, in a downstream portion of the separation region, wherein the horizontal reference plane intersects the froth layer, the first and second widths being measured in the horizontal reference plane in a direction substantially perpendicular to a centerline of the flow. 19. The vessel of claim 1 wherein the underflow outlet is operably configured to collect the water and fine solids stream while the overflow outlet collects the bitumen enriched froth stream. 20. The vessel of claim 1 wherein the overflow outlet comprises at least one weir oriented in a direction substantially perpendicular to a centerline of the flow. 21. A concentrator vessel for separating a bitumen froth stream containing bitumen froth, water and fine solids into first and second output streams, the vessel comprising: receiving means for receiving a flow of the bitumen froth stream;separation promotion means, in communication with the receiving means, for promoting separation of the bitumen froth from the water and fine solids, the bitumen froth accumulating as a froth layer atop a water layer with the fine solids settling within the water layer, the separation promotion means comprising flow slowing means for slowing the flow of the bitumen froth stream, wherein the separation promotion means comprises a diverging channel formed by first and second walls that are: (a) spaced apart in a horizontal reference plane by a first width in an upstream portion of the diverging channel; and (b) spaced apart in the horizontal reference plane by a second width, wider than the first width, in a downstream portion of the diverging channel, wherein the horizontal reference plane intersects the bitumen froth layer, and the first and second widths are measured in the horizontal reference plane in a direction substantially perpendicular to a centerline of the flow;recovery means, in communication with the separation promotion means, for recovering the bitumen froth from the flow;bitumen froth layer collection means, in communication with the recovery means, for collecting the bitumen froth layer as a bitumen enriched froth stream, wherein the first output stream of the vessel is the bitumen enriched froth stream; andwater and fine solids collection means for collecting the water and fine solids as a water and fine solids stream, wherein the second output stream of the vessel is the water and fine solids stream. 22. 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;a separation region in communication with the inlet region comprising a diverging channel adapted to slow the flow of the bitumen froth stream to promote separation of the bitumen froth from the water and fine solids, the bitumen froth accumulating as a froth layer atop a water layer with the fine solids settling within the water layer, wherein the diverging channel includes at least one turn to increase the length of the channel; anda 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; andan underflow outlet configured to collect the water and fine solids as the water and fine solids stream.
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