The present invention a s generally to the field of an offshore oil storage system and its method for use with offshore oil drilling and production facilities. More particularly, the invention relates to a vertical oil storage system and its water-displacement and oil-water separation method to displace water with oil or displace oil with water without discharging oil-contaminated water into open seawater directly.
The draft hull 204 can include three main components: a hard tank 206 located in the upper part of the draft hull 204 for providing buoyancy to support the topside facility 202, a mid tank 208 located below the hard tank 206 for oil storage or completely being flooded with seawater, and a soft tank 210 located at the bottom of the SPAR platform 100 for providing ballast for platform stability. The hard tank 206 includes a water ballast tank 214 at its lower end and a center well 212 located in the center of the hard tank 206. The center well 212 can be filled with water from top to bottom and directly connected with open seawater at the keel of the SPAR platform 100 via a water passageway 218 (or a riser guide tube), which is watertight and extends through the mid tank 208. A watertight deck 220 can be applied at the top (in the center well 212 of the hard tank 206) and the end (at the bottom of the soft tank 210) of the water passageway 218.
In a traditional SPAR platform, such as the SPAR platform 100 shown in
As described above, a need exists for an improved oil storage system to be applied with an offshore oil drilling and production platform.
A further need exists for an improved oil storage system with an improved water displacement method to separate oil from water before water being discharged into open seawater to avoid environmental pollution.
The present embodiments of the system and the method meet these needs and improve on the technology.
The drawings described herein are for illustrating purposes only of selected embodiments and not all possible implementation and are not intended to limit the scope of the present disclosure.
The detailed description will be better understood in conjunction with the accompanying drawings as follows:
The present embodiments are detailed below with reference to the listed Figures.
Before explaining the present invention in detail, it is to be understood that the present invention is not limited to the particular embodiments and that it can be practiced or carried in various ways.
It is understood that the vertical oil storage system and its method can be used in any body of water. The term “oil” can comprise crude oil and other hydrocarbon oils. The term “water” can comprise seawater and fresh water.
The invention relates to a vertical oil storage system and its water-displacement and oil-water separation method to displace oil with water or displace water with oil without discharging oil-contaminated water into open water directly.
The containment saucer 310 can be for containing the oil-water interface and separating the oil 322 from the water 324. Also, to further ensure the water 324 will not be contaminated by the oil 322 when it is discharged back to open water, when the produced oil 322 is loaded into the vertical oil storage system 300, corresponding amount of water 324, which is supposed to be offloaded out of the vertical oil storage system 300 into ambient water to keep platform stability, can be offloaded from the oil tank 308 to the upper water sump 314 in the center well 212 via the water pipe 304 first, instead of being discharged hack to open water via a water outlet 326 at the keel of the platform directly. in the upper water sump 314, even when the water 324, which is just loaded into the upper water sump 314 from the water caisson 312, still contains few amount of oil 322, the oil 322 would float above the water 324 in the upper water sump 314. Finally, the pure water 324, which has been gone through the oil-water separation process twice in the oil tank 308 and in the upper water sump 314, can be offloaded from the bottom of the center well 212 back to open water at the water outlet 326 at the keel of the platform via the water passageway 218. The long distance between the keel of the platform and the upper water sump 314 (typically more than 600 feet) can further enhance the oil-water separation process by gravity and guarantees that no oil will be discharged to the open water.
The oil caisson 306 can store substantially pure oil 322, even when the containment saucer 310 is located at the top of the oil tank 308 under the 1st boundary condition shown in
In some embodiments, a deck valve 316 can be applied at the bottom of the upper water sump 314 for separating the area of the upper water sump 314 from the center well 212. When the cleanness procedure of the upper water sump 314 is deemed necessary, the deck valve 316 can be closed to isolate the area of the upper water sump 314. Furthermore, it is easier to clean only the upper water sump 314 instead of the entire center well 212, because the upper water sump 314 is close to the waterline 200 and easy to be accessed to.
In some embodiments, the oil tank 308 can have a cofferdam 320 for a structural safety purpose. The cofferdam 320 preferably has a double hull structure. The space inside the cofferdam 320 can be filled with water and compressed air 318 for keeping the draft hull 204 at a constant level when the oil tank 308 is loading or offloading oil or water. Adjustment of the amount of water inside the cofferdam 320 can be achieved by pumping in/out water via a water pump (not shown in the
The containment saucer 310 can include an upper deck 404, a lower deck 406, and one or multiple baffle plates 402 located between the upper deck 404 and the lower deck 406. The upper deck 404 and the lower deck 406 can further include one or multiple saucer deck openings 408 for the water passageway 218 and the water pipe 304 to go through and to ensure that fluid communication in a vertical direction is not blocked by the containment saucer 310. In that way, the containment saucer 310 can float up and down smoothly with the movement of the oil-water interface 400. Based on the fact that the density of the containment saucer 310 is between the densities of the oil 322 and the water 324, the oil-water interface 400 can be well confined within the depth of the containment saucer 310. Therefore, the oil 322 above the containment saucer 310 and the water 324 below the containment saucer 310 can be adequately separated from each other. The baffles plates 402 can further reduce the free surface effect of the oil-water interface 400 and help minimize a mixture of the oil 322 and the water 324.
In some embodiments, the baffle plates 402 can also have one or multiple holes (not shown in
In some embodiments, loading oil from the topside facility into the oil caisson via an oil pipe 500 further includes the step of utilizing an oil pump to pump oil from the topside facility into the oil caisson.
In some embodiments, offloading water from the water caisson into the upper water sump via the water pipe 502 further includes the step of utilizing a water pump to pump the water from the water caisson into the upper water sump.
The present invention is in no way limited to being applied to an particular platform or body of water.
The present invention is in no way limited to being applied to any particular number of oil tanks, internal water pipes, internal oil pipes, water passageways, or containment saucers.
In conclusion, exemplary embodiments of the present invention stated above may provide several advantages as follows. The present invention utilizes an arrangement of a containment saucer, caissons, water and oil pipes, and a water passageway to separate oil from water before it being discharged into open water to prevent environmental pollution. Furthermore, the present invention makes it possible to apply the wet storage method to a conventional SPAR platform or any other platforms to store produced oil in order to save the cost for building expensive deepwater pipelines for oil export.