IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0072996
(2008-02-29)
|
등록번호 |
US-8281820
(2012-10-09)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
16 인용 특허 :
32 |
초록
▼
Methods for loading a compressed fluid, such as natural gas, into and discharging the compressed fluid out of containment are provided. The compressed fluid is injected into a bottom portion of a container system for storage and/or transport until a target pressure is reached after which gas is with
Methods for loading a compressed fluid, such as natural gas, into and discharging the compressed fluid out of containment are provided. The compressed fluid is injected into a bottom portion of a container system for storage and/or transport until a target pressure is reached after which gas is withdrawn from an upper portion of the container system at a rate to maintain the target pressure while the compressed fluid is injected in the bottom portion. The compressed fluid is cooled through an expansion valve and by refrigerated chillers or by injecting a cold liquid of the same chemical composition as the compressed fluid, such as liquid natural gas, into the compressed fluid prior to injection into the container system. Withdrawal or discharge from the container system to a receiving facility begins with blow down from the bottom portion of the container system without a displacement fluid and continues until pressure falls below an acceptable differential pressure. The discharge stream is passed through a separator and a light gas from the separator is pressurized and injected into an upper portion of the container system to drive the compressed fluid out the bottom. The light gas is pressurized using either a compressor or a heated tank system, where two vessels operate in parallel, trapping and heating the light gas and then discharging to the container system from one while filling the other and alternating the operation between the two.
대표청구항
▼
1. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed natural gas that is contained in the containment system into the receiving system, wherein the pressure in the containme
1. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed natural gas that is contained in the containment system into the receiving system, wherein the pressure in the containment system is higher than the pressure in the receiving system, wherein the containment system has an upper portion and a lower portion, wherein the compressed natural gas is liquid and/or more dense in the lower portion of the containment system than in the upper portion, and wherein the flow path connects to the lower portion of the containment system; andallowing flow to occur from the lower portion of the containment system to the receiving system prior to allowing flow to occur from the upper portion of the containment system, while not adding any fluid into the containment system, until the pressure in the containment system drops to a point such that the actual flow rate from the lower portion of the containment system is at or below a desired flow rate. 2. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed natural gas that is contained in the containment system into the receiving system, wherein the pressure in the containment system is higher than the pressure in the receiving system, wherein the containment system has an upper portion and a lower portion, wherein the compressed natural gas is liquid and/or more dense in the lower portion of the containment system than in the upper portion, and wherein the flow path connects to the upper and lower portions of the containment system; andallowing flow to occur from the upper portion of the containment system to the receiving system prior to allowing flow to occur from the lower portion of the containment system, while not adding any fluid into the containment system, until the pressure in the containment system drops to a point such that the actual flow rate from the upper portion of the containment system is at or below a desired flow rate. 3. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed fluid that is contained in the containment system into the receiving system, wherein the pressure in the containment system is higher than the pressure in the receiving system, wherein the containment system has an upper portion and a lower portion, and wherein the flow path connects to the lower portion of the containment system; andallowing flow to occur from the lower portion of the containment system to the receiving system, while not adding any fluid into the containment system, until the pressure in the containment system drops to a point such that the actual flow rate in the flow path is at or below a desired flow rate,wherein a separator is provided in the flow path for separating the compressed fluid into a lower density stream and a higher density stream, and wherein after the pressure in the containment system drops to the point such that the actual flow rate in the flow path is nearly at or below the desired flow rate, further comprising:injecting the lower density stream from the separator into a compressor;compressing the lower density stream to form a displacement fluid;injecting the displacement fluid into the upper portion of the containment system for pushing the compressed fluid out the lower portion of the containment system; andallowing the higher density stream to flow to the receiving system. 4. The method of claim 3, further comprising controlling the temperature of the displacement fluid to avoid thermally shocking the upper portion of the containment system. 5. The method of claim 4, further comprising increasing the temperature of the displacement fluid as the amount of compressed fluid in the containment system decreases. 6. The method of claim 3, further comprising shutting in the containment system when a desired amount of compressed fluid has been removed from the containment system. 7. The method of claim 6, further comprising withdrawing gas from the containment system with a scavenging compressor after shutting in the containment system. 8. The method of claim 3, wherein the containment system is on a marine vessel, and wherein the compressed fluid is compressed natural gas. 9. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed fluid that is contained in the containment system into the receiving system, wherein the pressure in the containment system is higher than the pressure in the receiving system, wherein the containment system has an upper portion and a lower portion, and wherein the flow path connects to the lower portion of the containment system; andallowing flow to occur from the lower portion of the containment system to the receiving system, while not adding any fluid into the containment system, until the pressure in the containment system drops to a point such that the actual flow rate in the flow path is at or below a desired flow rate,wherein a separator is provided in the flow path for separating the compressed fluid into a lower density stream and a higher density stream, and wherein after the pressure in the containment system drops to the point such that the actual flow rate in the flow path is nearly at or below the desired flow rate, further comprising:injecting the lower density stream from the separator into a vessel;trapping a desired quantity of the lower density stream in the vessel;heating the lower density stream to form a displacement fluid;injecting the displacement fluid into the upper portion of the containment system for pushing the compressed fluid out the lower portion of the containment system; andallowing the higher density stream to flow to the receiving system. 10. The method of claim 9, further comprising a tank that is essentially identical to the vessel, wherein the tank is placed in a flow configuration parallel with the flow configuration of the vessel, further comprising injecting the lower density stream from the separator into the tank while the vessel forms the displacement fluid and while the displacement fluid is injected into the upper portion of the containment system. 11. The method of claim 10, further comprising: trapping the lower density stream in the tank and heating the lower density stream to form a displacer fluid while injecting the lower density stream from the separator into the vessel; andinjecting the displacer fluid into the upper portion of the containment system after the displacement fluid is depleted from the vessel such that the vessel and the tank are operated alternately to push the compressed fluid out the lower portion of the containment system. 12. The method of claim 9, wherein the containment system is on a marine vessel, and wherein the compressed fluid is compressed natural gas. 13. A method for discharging a compressed fluid from containment, comprising: providing a flow path between a containment system and a receiving system for discharging a compressed fluid that is contained in the containment system into the receiving system, wherein the pressure in the containment system is higher than the pressure in the receiving system, wherein the containment system has an upper portion and a lower portion, and wherein the flow path connects to the lower portion of the containment system; andallowing flow to occur from the lower portion of the containment system to the receiving system, while not adding any fluid into the containment system, until the pressure in the containment system drops to a point such that the actual flow rate in the flow path is at or below a desired flow rate,wherein a separator is provided in the flow path for separating the compressed fluid into a lower density stream and a higher density stream, and wherein after the pressure in the containment system drops to the point such that the actual flow rate in the flow path is nearly at or below the desired flow rate, further comprising:injecting the higher density stream from the separator into a first container;trapping a desired quantity of the higher density stream in the first container;heating the higher density stream to form a higher-pressure fluid; andinjecting the higher-pressure fluid into the receiving system. 14. The method of claim 13, further comprising a second container that is essentially identical to the first container, wherein the second container is placed in a flow configuration parallel with the flow configuration of the first container, further comprising injecting the higher density stream from the separator into the second container while the first container forms the higher-pressure fluid and while the higher-pressure fluid is injected into the receiving system. 15. The method of claim 14, further comprising: trapping the higher density stream in the second container and heating the higher density stream to form a high-pressure fluid while injecting the higher density stream from the separator into the first container; andinjecting the high-pressure fluid into the receiving system after the higher-pressure fluid is depleted from the first container such that the first container and the second container are operated alternately to convey the higher density stream from the separator into the receiving system. 16. The method of claim 15, further comprising pushing compressed fluid out of the containment system according to the method of claim 3. 17. The method of claim 15, further comprising pushing compressed fluid out of the containment system according to the method of claim 9. 18. A method for transporting natural gas with a ship, comprising: berthing a ship near a source of compressed natural gas (CNG);providing a flow path from the source of CNG to a plurality of tanks located in a plurality of cargo holds on the ship, the plurality of tanks including a first tank and a second tank, each tank having an upper portion and a lower portion;injecting a displacement fluid into the first tank, wherein the displacement fluid is a gas under the conditions inside the first tank;injecting the displacement fluid and/or the CNG into the first tank until a desired pressure is reached in the first tank, wherein the CNG is injected into the lower portion of the first tank;withdrawing the displacement fluid out of the upper portion of the first tank after the desired pressure is attained while continuing to inject the CNG into the lower portion of the first tank;adjusting the flow rate of the displacement fluid withdrawn out of the upper portion of the first tank to maintain the pressure in the first tank within a desired range about the desired pressure;injecting the CNG into the lower portion of the first tank until a desired mass of the CNG is contained in the first tank while withdrawing the displacement fluid out of the upper portion of the first tank;maintaining a desired temperature of the CNG prior to injecting the CNG into the first tank;injecting the gas withdrawn from the first tank into the upper portion of the second tank;maintaining the pressure in the first tank within a desired range about the desired pressure in the first tank by adjusting the flow rate of the gas withdrawn from the upper portion while continuing to inject CNG into the lower portion;loading a desired amount of CNG into the first tank and thereafter shutting in the first tank;loading a desired amount of CNG into the second tank and into each of the remaining tanks in the plurality of tanks using the same method as used to load and shut in the first tank;transporting the CNG by moving the ship;berthing the ship near a receiving facility;providing a flow way between the plurality of tanks on the ship and the receiving facility for discharging the CNG into the receiving facility, wherein the pressure in the plurality of tanks is higher than the pressure in the receiving facility, wherein the flow way connects to the lower portion of each of the plurality of tanks; andallowing flow to occur from the plurality of tanks to the receiving facility, while not adding any fluid into the plurality of tanks, until the pressure in the plurality of tanks drops to a point such that a measured flow rate in the flow way is at or below a desired flow rate. 19. The method of claim 18, wherein a separator is provided in the flow way for separating the CNG into a lower density stream and a higher density stream, and wherein after the pressure in the plurality of tanks drops to the point such that the measured flow rate in the flow way is nearly at or below the desired flow rate, further comprising: injecting the lower density stream from the separator into a compressor;compressing the lower density stream to form a displacement fluid;injecting the displacement fluid into the upper portion of each of the tanks in the plurality of tanks for pushing the CNG out the lower portion of each of the tanks in the plurality of tanks; andallowing the higher density stream to flow to the receiving facility. 20. The method of claim 18, wherein a separator is provided in the flow way for separating the CNG into a lower density stream and a higher density stream, and wherein after the pressure in the plurality of tanks drops to the point such that the actual flow rate in the flow way is nearly at or below the desired flow rate, further comprising: injecting the lower density stream from the separator into a first vessel;trapping a desired quantity of the lower density stream in the first vessel;heating the lower density stream to form a displacement fluid;injecting the displacement fluid into the upper portion of each of the tanks in the plurality of tanks for pushing the compressed fluid out the lower portion of each of the tanks in the plurality of tanks; andallowing the higher density stream to flow to the receiving facility. 21. The method of claim 20, further comprising a second vessel that is essentially identical to the first vessel, wherein the second vessel is placed in a flow configuration parallel with the flow configuration of the first vessel, further comprising injecting the lower density stream from the separator into the second vessel while the first vessel forms the displacement fluid and while the displacement fluid is injected into the upper portion of each of the tanks in the plurality of tanks. 22. The method of claim 21, further comprising: trapping the lower density stream in the second vessel and heating the lower density stream to form a displacer fluid while injecting the lower density stream from the separator into the first vessel; andinjecting the displacer fluid into the upper portion of the tanks in the plurality of tanks after the displacement fluid is depleted from the first vessel such that the first vessel and the second vessel are operated alternately to push the CNG out the lower portion of each of the tanks in the plurality of tanks.
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