Power generation from waste heat in integrated aromatics and naphtha block facilities
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01D-015/10
F02C-006/00
H02K-007/18
H02P-009/04
F01K-013/02
C10G-057/00
F01D-017/14
F01K-003/18
C10G-059/00
C10G-061/00
C10G-063/00
F01K-003/00
F01K-027/00
C10G-099/00
C10G-053/04
C10G-055/00
C10G-061/10
F02B-063/04
F03G-007/08
출원번호
US-0087403
(2016-03-31)
등록번호
US-9803505
(2017-10-31)
발명자
/ 주소
Noureldin, Mahmoud Bahy Mahmoud
Al Saed, Hani Mohammed
Bunaiyan, Ahmad Saleh
출원인 / 주소
Saudi Arabian Oil Company
대리인 / 주소
Fish & Richardson P.C.
인용정보
피인용 횟수 :
1인용 특허 :
29
초록▼
Optimizing power generation from waste heat in large industrial facilities such as petroleum refineries by utilizing a subset of all available hot source streams selected based, in part, on considerations for example, capital cost, ease of operation, economics of scale power generation, a number of
Optimizing power generation from waste heat in large industrial facilities such as petroleum refineries by utilizing a subset of all available hot source streams selected based, in part, on considerations for example, capital cost, ease of operation, economics of scale power generation, a number of ORC machines to be operated, operating conditions of each ORC machine, combinations of them, or other considerations are described. Recognizing that several subsets of hot sources can be identified from among the available hot sources in a large petroleum refinery, subsets of hot sources that are optimized to provide waste heat to one or more ORC machines for power generation are also described. Further, recognizing that the utilization of waste heat from all available hot sources in a mega-site such as a petroleum refinery and aromatics complex is not necessarily or not always the best option, hot source units in petroleum refineries from which waste heat can be consolidated to power the one or more ORC machines are identified.
대표청구항▼
1. A power generation system, comprising: a first heating fluid circuit thermally coupled to a first plurality of heat sources from a first plurality of sub-units of a petrochemical refining system, the first plurality of sub-units comprising a continuous catalytic reforming (CCR), a para-xylene sep
1. A power generation system, comprising: a first heating fluid circuit thermally coupled to a first plurality of heat sources from a first plurality of sub-units of a petrochemical refining system, the first plurality of sub-units comprising a continuous catalytic reforming (CCR), a para-xylene separation system, and an aromatics complex-benzene extraction system;a second heating fluid circuit thermally coupled to a second plurality of heat sources from a second plurality of sub-units of the petrochemical refining system, the second plurality of sub-units comprising a para-xylene separation unit;a power generation sub-system that comprises an organic Rankine cycle (ORC), the ORC comprising (i) a working fluid that is thermally coupled to the first and second heating fluid circuits to heat the working fluid, and (ii) an expander configured to generate electrical power from the heated working fluid; anda control system configured to actuate a first set of control valves to selectively thermally couple the first heating fluid circuit to at least a portion of the first plurality of heat sources, and the control system is configured to actuate a second set of control valves to selectively thermally couple the second heating fluid circuit to at least a portion of the second plurality of heat sources. 2. The power generation system of claim 1, wherein the working fluid is thermally coupled to the first heating fluid circuit in a pre-heating heat exchanger of the ORC, and the working fluid is thermally coupled to the second heating fluid circuit in an evaporator of the ORC, and an outlet of the pre-heating heat exchanger of the ORC is fluidly coupled to the evaporator of the ORC. 3. The power generation system of claim 2, wherein the first heating fluid circuit comprises a first heating fluid tank that is fluidly coupled to the first and second heating fluid circuits, and the first heating fluid tank is fluidly coupled with the pre-heating heat exchanger of the ORC. 4. The power generation system of claim 1, wherein the working fluid comprises isobutane. 5. The power generation system of claim 1, wherein the first or second heating fluid circuits comprises water or oil. 6. The power generation system of claim 1, wherein the ORC further comprises: a condenser fluidly coupled to a condenser fluid source to cool the working fluid; anda pump to circulate the working fluid through the ORC. 7. The power generation system of claim 1, wherein a first sub-set of the first plurality of heat sources comprises three para-xylene separation unit heat sources, comprising: a first para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a raw paraxylene stream circulated through an air cooler to a storage tank, and is fluidly coupled to the first heating fluid circuit;a second para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a paraxylene purification stream circulated through an air cooler to a paraxylene purification reflux drum, and is fluidly coupled to the first heating fluid circuit; anda third para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a C9+ARO stream circulated through an air cooler to a C9+ARO storage, and is fluidly coupled to the first heating fluid circuit;a second sub-set of the first plurality of heat sources comprises two para-xylene separation-xylene isomerization reaction and separation unit heat sources, comprising: a first para-xylene separation-xylene isomerization reaction and separation unit heat source comprising a heat exchanger that is fluidly coupled to a Xylene isomerization reactor outlet stream before a separator drum, and is fluidly coupled to the first heating fluid circuit; anda second para-xylene separation-xylene isomerization reaction and separation unit heat source comprises a heat exchanger that is fluidly coupled to a de-heptanizer column overhead stream, and is fluidly coupled to the first heating fluid circuit;a third sub-set of the first plurality of heat sources comprises at least one aromatics complex-benzene extraction unit heat source, comprising a heat exchanger that is fluidly coupled to an overhead stream, and is fluidly coupled to the first heating fluid circuit; anda fourth sub-set of the first plurality of heat sources comprises four continuous catalytic cracking heat sources, comprising: a first continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a CCR last stage reactor outlet after the feed-effluent heat exchanger stream, and is fluidly coupled to the first heating fluid circuit;a second continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a 1st stage compressor outlet stream, and is fluidly coupled to the first heating fluid circuit;a third continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a 2nd stage compressor outlet stream, and is fluidly coupled to the first heating fluid circuit; anda fourth continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a CCR light reformate splitter column overhead stream, and is fluidly coupled to the first heating fluid circuit. 8. The power generation system of claim 7, wherein a first sub-set of the second plurality of heat sources comprises three para-xylene separation unit heat sources, comprising: a first para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a para-xylene unit external column overhead stream, and is fluidly coupled to the second heating fluid circuit;a second para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a Raffinate column overhead stream, and is fluidly coupled to the second heating fluid circuit; anda third para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a heavy Raffinate splitter column overhead stream, and is fluidly coupled to the second heating fluid circuit. 9. A method of recovering heat energy generated by a petrochemical refining system, the method comprising: circulating a first heating fluid through a first heating fluid circuit thermally coupled to a first plurality of heat sources from a first plurality of sub-units of a petrochemical refining system, the first plurality of sub-units comprising a continuous catalytic reforming (CCR), a para-xylene separation system, and aromatics refining and an aromatics complex-benzene extraction system;circulating a second heating fluid through a second heating fluid circuit thermally coupled to a second plurality of heat sources of a second plurality of sub-units of the petrochemical refining system, the second plurality of sub-units comprises a para-xylene separation unit;generating electrical power through a power generation system that comprises an organic Rankine cycle (ORC), the ORC comprising (i) a working fluid that is thermally coupled to the first and second heating fluid circuits to heat the working fluid with the first and second heating fluids, and (ii) an expander configured to generate electrical power from the heated working fluid;actuating, with a control system, a first set of control valves to selectively thermally couple the first heating fluid circuit to at least a portion of the first plurality of heat sources to heat the first heating fluid with the first plurality of heat sources; andactuating, with the control system, a second set of control valves to selectively thermally couple the second heating fluid circuit to at least a portion of the second plurality of heat sources to heat the second heating fluid with the second plurality of heat sources. 10. The method of claim 9, wherein the working fluid is thermally coupled to the first heating fluid circuit in a pre-heating heat exchanger of the ORC, and the working fluid is thermally coupled to the second heating fluid circuit in an evaporator of the ORC, and an outlet of the pre-heating heat exchanger of the ORC is fluidly coupled to the evaporator of the ORC. 11. The method of claim 10, wherein the first heating fluid circuit comprises a first heating fluid tank that is fluidly coupled to the first and second heating fluid circuits, and the first heating fluid tank is fluidly coupled with the pre-heating heat exchanger of the ORC. 12. The method of claim 9, wherein the working fluid comprises isobutane. 13. The method of claim 9, wherein the first or second heating fluid circuits comprises water or oil. 14. The method of claim 9, wherein the ORC further comprises: a condenser fluidly coupled to a condenser fluid source to cool the working fluid; anda pump to circulate the working fluid through the ORC. 15. The method of claim 9, wherein a first sub-set of the first plurality of heat sources comprises three para-xylene separation unit heat sources, comprising: a first para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a raw paraxylene stream circulated through an air cooler to a storage tank, and is fluidly coupled to the first heating fluid circuit;a second para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a paraxylene purification stream circulated through an air cooler to a paraxylene purification reflux drum, and is fluidly coupled to the first heating fluid circuit; anda third para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a C9+ARO stream circulated through an air cooler to a C9+ARO storage, and is fluidly coupled to the first heating fluid circuit;a second sub-set of the first plurality of heat sources comprises two para-xylene separation-xylene isomerization reaction and separation unit heat sources, comprising: a first para-xylene separation-xylene isomerization reaction and separation unit heat source comprising a heat exchanger that is fluidly coupled to a Xylene isomerization reactor outlet stream before a separator drum, and is fluidly coupled to the first heating fluid circuit; anda second para-xylene separation-xylene isomerization reaction and separation unit heat source comprises a heat exchanger that is fluidly coupled to a de-heptanizer column overhead stream, and is fluidly coupled to the first heating fluid circuit;a third sub-set of the first plurality of heat sources comprises at least one aromatics complex-benzene extraction unit heat source, comprising a heat exchanger that is fluidly coupled to an overhead stream, and is fluidly coupled to the first heating fluid circuit; anda fourth sub-set of the first plurality of heat sources comprises four continuous catalytic cracking heat sources, comprising: a first continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a CCR last stage reactor outlet after the feed-effluent heat exchanger stream, and is fluidly coupled to the first heating fluid circuit;a second continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a 1st stage compressor outlet stream, and is fluidly coupled to the first heating fluid circuit;a third continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a 2nd stage compressor outlet stream, and is fluidly coupled to the first heating fluid circuit; anda fourth continuous catalytic cracking heat source comprising a heat exchanger that is fluidly coupled to a CCR light reformate splitter column overhead stream, and is fluidly coupled to the first heating fluid circuit. 16. The method of claim 15, wherein a first sub-set of the second plurality of heat sources comprises three para-xylene separation unit heat sources, comprising: a first para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a para-xylene unit extract column overhead stream, and is fluidly coupled to the second heating fluid circuit;a second para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a Raffinate column overhead stream, and is fluidly coupled to the second heating fluid circuit; anda third para-xylene separation unit heat source comprising a heat exchanger that is fluidly coupled to a heavy Raffinate splitter column overhead stream, and is fluidly coupled to the second heating fluid circuit. 17. A method of recovering heat energy generated by a petrochemical refining system, the method comprising: identifying, in a geographic layout, a first heating fluid circuit thermally coupled to a first plurality of heat sources from a first plurality of sub-units of a petrochemical refining system, the first plurality of sub-units comprising a continuous catalytic reforming (CCR), a para-xylene separation system, and aromatics refining and an aromatics complex-benzene extraction system;identifying, in the geographic layout, a second heating fluid through a second heating fluid circuit thermally coupled to a second plurality of heat sources of a second plurality of sub-units of the petrochemical refining system, the second plurality of sub-units comprising a para-xylene separation unit;identifying, in the geographic layout, a power generation system, comprising: an organic Rankine cycle (ORC), the ORC comprising (i) a working fluid that is thermally coupled to the first and second heating fluid circuits to heat the working fluid with the first and second heating fluids, and (ii) an expander configured to generate electrical power from the heated working fluid; anda control system configured to actuate a first set of control valves to selectively thermally couple the first heating fluid circuit to at least a portion of the first plurality of heat sources, and the control system is configured to actuate a second set of control valves to selectively thermally couple the second heating fluid circuit to at least a portion of the second plurality of heat sources; andidentifying, in the geographic layout, a power generation system location to position the power generation system, wherein a heat energy recovery efficiency at the power generation system location is greater than a heat energy recovery efficiency at other locations in the geographic layout. 18. The method of claim 17, further comprising constructing the petrochemical refining system according to the geographic layout by positioning the plurality of sub-units at the plurality of sub-unit locations, positioning the power generation system at the power generation system location, interconnecting the plurality of sub-units with each other such that the interconnected plurality of sub-units are configured to refine petrochemicals, and interconnecting the power generation system with the sub-units in the first subset such that the power generation system is configured to recover heat energy from the sub-units in the first subset and to provide the recovered heat energy to the power generation system, the power generation system configured to generate power using the recovered heat energy. 19. The method of claim 17, further comprising: operating the petrochemical refining system to refine petrochemicals; andoperating the power generation system to: recover heat energy from the sub-units in the first subset through the first heating fluid circuit and the second heating fluid circuit;provide the recovered heat energy to the power generation system; andgenerate power using the recovered heat energy. 20. The method of claim 17, further comprising operating the power generation system to generate about 37 MW of power.
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