The present invention relates to a system for forming an aqueous slurry of oil sand, so that the slurry is suitable for hydrotransport. The system has process and apparatus aspects.
Over the past 30 years, as-mined oil sand containing bitumen has been slurried and conditioned at applicants' facilities in two different ways.
In the earlier process, the excavated or ‘as-mined’ oil sand was comminute to conveyable size (e.g. −24 inches) with a roll crusher at the mine site and transported on belt conveyors to a central bitumen extraction plant. Here the pre-crushed oil sand was fed into the front end of a horizontal rotating tumbler. Hot water (e.g. 95° C.) was also added, together with a small amount of caustic. The resulting slurry was cascaded as it advanced through the large tumbler over a period of several minutes. Steam was sparged into the slurry to ensure that it was at a temperature of about 80° C. when it exited the tumbler. During this passage through the tumbler, the slurry was ‘conditioned’. That is, lumps were ablated, bitumen flecks were dispersed into the water phase, the flecks coalesced into small droplets and bitumen droplets contacted and adhered to entrained air bubbles. The emerging conditioned slurry was screened to remove oversize and was then ‘flooded’ or diluted with additional hot water. The resulting diluted slurry was introduced into a gravity separation vessel (referred to as a ‘PSV’). The PSV was a large, cylindrical, open-topped vessel having a conical bottom. During retention in the PSV, buoyant aerated bitumen rose to form a top layer of froth, which was removed. The sand settled, was concentrated in the conical base and was separately removed.
If the oil sand was of acceptable quality (for example if it contained >10% by weight bitumen) and if conditioning was properly carried out, recovery of bitumen in the PSV was in the order of 95% by weight.
Over time, the mine faces moved further from the central extraction plant. New mines were also opened that were distant (for example, 25 kilometers away). In addition the belt conveyors were expensive and difficult to operate.
Through research and testing, it was found that if the oil sand was slurried and pumped through a pipeline for a minimum retention time, it would be conditioned as it traveled therethrough and could be fed directly into a PSV with acceptable resulting bitumen recovery.
This led to the implementation of the second system, which is commonly referred to as the ‘hydrotransport system’. One embodiment, referred to as the ‘Aurora’ facility involves:
There are some problems associated with the Aurora facility. For example:
In accordance with the present invention, screening and reject treatment are eliminated from slurry preparation as a result of using a plurality of size reduction stages, combined with process water addition and mixing, to convert all of the as-mined oil sand supplied into a slurry of a pumpable size.
In one apparatus embodiment of the invention, there is provided an assembly of components for producing a pumpable oil sand slurry at a mine site, for transmission through a pump and pipeline system, comprising:
In another embodiment there is provided a process for producing a pumpable oil sand slurry at a mine site for transmission through a pump and pipeline system, comprising:
The present invention is concerned with processing as-mined oil sand at the mine site to convert it to a pumpable slurry which is capable of being hydrotransported through a pump and pipeline system.
This is preferably done using an assembly of components which are compact and relocatable, so that the assembly can follow the advancing mine face. The components may be mobile, for example by being mounted on driven tracks, or they may be adapted for easy disassembly for periodic moving and reassembly. The term ‘relocatable’ is intended to describe both versions.
Turning now to the specific embodiment shown in
The pre-crushed oil sand 7 is transported by a belt conveyor assembly 8 and is delivered into a dry ore surge bin 10.
The rectangular surge bin 10 is three sided, having an open side 11. A pair of parallel apron feeders 12, 13 extend into the base of the surge bin 10 for removing pre-crushed oil sand 7 at a slow, controlled, sustained mass flow rate. The apron feeders 12, 13 are upwardly inclined and transport and feed the pre-crushed oil sand 7 to the upper end of a slurry preparation tower 14.
The slurry preparation tower 14 comprises an arrangement of downwardly sequenced components, which rely on gravity feed.
More particularly, the tower 14 provides a stack 15 of two secondary roll crushers 16, 17, which sequentially comminute the pre-crushed oil sand 7 to attain pumpable size. Since the maximum present day pumpable slurry particle size is about 8 inches, the stack 15 of secondary roll crushers is designed to reduce the particle size, preferably to about −4 inches. This allows for some wear of the crusher rolls before requiring repair or replacement. Preferably the uppermost roll crusher 16 is selected to reduce the particle size to about −8 inches and the lowermost roll crusher 17 completes the size reduction to about −4 inches.
Heated water is added to the oil sand 7 in the course of size reduction. This is accomplished by spraying the stream of oil sand 18 being secondarily crushed with a plurality of nozzle manifolds 19 located above, between and below the crushers 16, 17, as shown. Sufficient water is added to preferably achieve a mixture 20 content of about 1.5 specific gravity.
The mixture 20 of comminuted oil sand and water drops into and moves downwardly through a mixing box 21. The mixing box 21 comprises a plurality of overlapping, downwardly inclined, descending shelves 22. The oil sand and water mix turbulently as they move through the box 21 and form a pumpable slurry 23.
The slurry 23 drops into and is temporarily retained in a pump box 24. The pump box 24 is connected with a pump and pipeline system 25. The pump box 24 feeds the system 25, which in turn transports the slurry 23 to the next stage of treatment (not shown).
As shown, the surge bin 10, apron feeders 12, 13, and slurry preparation tower 14 (including the secondary roll crushers 16, 17, water nozzle manifolds 19, mixing box 21 and pump box 24) are mounted on a common structural frame 26. The frame 26 is preferably mounted on tracks 27, so that the entire assembly may periodically be advanced to a new location.
The combination of the preferred embodiment described is characterized by the following advantages:
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5772127 | Maciejewski et al. | Jun 1998 | A |
5954277 | Maciejewski et al. | Sep 1999 | A |
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2195604 | Jul 1998 | CA |
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Number | Date | Country | |
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20060043005 A1 | Mar 2006 | US |