Power generation using independent triple organic rankine cycles from waste heat in integrated crude oil refining and aromatics facilities
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01K-025/06
F01K-027/02
F01K-025/08
F28D-007/00
C10G-045/02
C10G-035/04
C10L-003/10
C07C-007/08
C10G-065/12
C10G-033/06
B01D-003/00
B01D-003/32
B01D-051/10
B01D-053/047
B01D-053/14
B01D-053/18
B01D-053/34
B01D-053/48
B01D-053/86
B01D-053/96
C02F-001/58
C10G-045/44
C10G-047/00
F28F-009/26
C10G-065/00
F01D-017/14
F01K-003/18
F01K-013/02
H02K-007/18
C10G-069/00
F01K-013/00
F01K-023/06
C01B-003/24
C10G-045/00
C10K-003/04
F01K-027/00
C02F-101/10
C02F-101/16
C02F-103/18
C02F-103/36
출원번호
US-0087503
(2016-03-31)
등록번호
US-9816759
(2017-11-14)
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 :
0인용 특허 :
28
초록▼
A power generation system includes four heating fluid circuits thermally coupled to heat sources from sub-units of a petrochemical refining system. The sub-units include a hydrocracking plant, an aromatics plant, and a diesel hydro-treating plant. Subsets of the heat sources includes hydrocracking p
A power generation system includes four heating fluid circuits thermally coupled to heat sources from sub-units of a petrochemical refining system. The sub-units include a hydrocracking plant, an aromatics plant, and a diesel hydro-treating plant. Subsets of the heat sources includes hydrocracking plant heat exchangers coupled to streams in the hydrocracking plant, aromatics plant heat exchangers coupled to streams in the aromatics plant, and diesel hydro-treating plant heat exchangers coupled to streams in the diesel hydro-treating plant. A power generation system includes three organic Rankine cycles, each including a working fluid that is thermally coupled to at least one heating fluid circuit to heat the working fluid, and an expander to generate electrical power from the heated working fluid. The system includes a control system to activate a set of control valves to selectively thermally couple each heating fluid circuit to at least a portion of the heat sources.
대표청구항▼
1. A power generation system comprising: a first heating fluid circuit thermally coupled to a plurality of heat sources from a plurality of sub-units of a petrochemical refining system;a second heating fluid circuit thermally coupled to the plurality of heat sources from the plurality of sub-units o
1. A power generation system comprising: a first heating fluid circuit thermally coupled to a plurality of heat sources from a plurality of sub-units of a petrochemical refining system;a second heating fluid circuit thermally coupled to the plurality of heat sources from the plurality of sub-units of the petrochemical refining system;a third heating fluid circuit thermally coupled to the plurality of sources from the plurality of sub-units of the petrochemical refining system;a fourth heating fluid circuit thermally coupled to the plurality of sources from the plurality of sub-units of the petrochemical refining system, wherein the plurality of sub-units comprises a hydrocracking plant, an aromatics plant, and a diesel hydro-treating plant, wherein a first subset of the plurality of heat sources comprises a plurality of aromatics plant heat exchangers coupled to streams in the aromatics plant,wherein a second subset of the plurality of heat sources comprises a plurality of hydrocracking plant heat exchangers coupled to streams in the hydrocracking plant, andwherein a third subset of the plurality of heat sources comprises a plurality of diesel hydro-treating plant heat exchangers coupled to streams in the diesel hydro-treating plant;a first power generation system, a second power generation system, and a third power generation system comprising a first organic Rankine cycle (ORC), a second ORC and a third ORC, respectively, the first ORC comprising (i) a first working fluid that is thermally coupled to the first heating fluid circuit and the second heating fluid circuit to heat the first working fluid, and (ii) a first expander configured to generate electrical power from the heated first working fluid,the second ORC comprising (i) a second working fluid that is thermally coupled to the third heating fluid circuit to heat the second working fluid, and (ii) a second expander configured to generate electrical power from the heated second working fluid, andthe third ORC comprising (i) a third working fluid that is thermally coupled to the fourth heating fluid circuit, and (ii) a third expander configured to generate electrical power from the heated third working fluid; anda control system configured to activate a set of control valves to selectively thermally couple each of the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit and the fourth heating fluid circuit to at least a portion of the plurality of heat sources. 2. The system of claim 1, wherein: the first working fluid is thermally coupled to the first heating fluid circuit in a first pre-heater of the first ORC and to the second heating fluid circuit in a first evaporator of the first ORC,the second working fluid is thermally coupled to the second heating fluid circuit in a second evaporator of the second ORC, andthe third working fluid is thermally coupled to the third heating fluid circuit in a third evaporator of the third ORC. 3. The system of claim 2, wherein each of the first working fluid, the second working fluid or the third working fluid comprises isobutane. 4. The system of claim 1, wherein the first heating fluid circuit, third heating fluid circuit and the fourth heating fluid circuit are fluidly connected to a first heating fluid tank, and wherein the second heating fluid circuit is fluidly connected to a second heating fluid tank. 5. The system of claim 1, wherein the plurality of heat sources in the first heating fluid circuit are fluidly coupled in parallel, wherein the plurality of heat sources in the second heating fluid circuit are fluidly coupled in parallel, wherein the plurality of heat sources in the third heating fluid circuit are fluidly coupled in parallel, and wherein the plurality of heat sources in the fourth heating fluid circuit are fluidly coupled in parallel. 6. The system of claim 1, wherein: each hydrocracking plant heat exchanger comprises a respective stream circulated through the hydrocracking plant and a portion of the heating fluid,each aromatics plant heat exchanger comprises a respective stream circulated through the aromatics plant and a portion of the heating fluid, and each diesel hydro-treating plant heat exchanger comprises a respective stream circulated through the diesel hydro-treating plant and a portion of the heating fluid. 7. The system of claim 6, wherein: the aromatics plant comprises a para-xylene separation unit, and wherein a first aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between an extract column overhead stream in the para-xylene separation unit and a portion of the heating fluid,a second aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a PX purification column bottom product stream in the para-xylene separation unit and a portion of the heating fluid,a third aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a heavy Raffinate column splitter and a portion of the heating fluid,a fourth aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a Raffinate splitter column overhead stream and a portion of the heating fluid,a fifth aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a Xylene isomerization reactor outlet stream and a portion of the heating fluid,a sixth aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a de-heptanizer column overhead stream in a xylene isomerization de-heptanizer in the aromatics plant and a portion of the heating fluid,a seventh aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a benzene column overhead stream in an aromatics benzene extraction unit in the aromatics plant and a portion of the heating fluid,an eighth aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between an extractive distillation column overhead stream in an aromatics complex extractive distillation column unit in the aromatics plant and a portion of the heating fluid, anda ninth aromatics plant heat exchanger in the first heating fluid circuit exchanges heat between a Raffinate splitter overhead stream in an aromatics complex raffinate splitter in the aromatics plant and a portion of the heating fluid. 8. The system of claim 7, wherein: a first aromatics plant heat exchanger in the second heating fluid circuit exchanges heat between a PX purification column overhead stream in the aromatics plant and a portion of the heating fluid, anda second aromatics plant heat exchanger in the second heating fluid circuit exchanges heat between a Raffinate column overhead stream in the aromatics plant and a portion of the heating fluid. 9. The system of claim 8, wherein: a first hydrocracking plant heat exchanger in third heating fluid circuit exchanges heat between a 2nd stage reaction section feed stream to 2nd stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,a second hydrocracking plant heat exchanger in third heating fluid circuit exchanges heat between a 1st stage reaction section feed stream to 1st stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,a third hydrocracking plant heat exchanger in third heating fluid circuit exchanges heat between a hydrocracking product stripper overhead stream in the hydrocracking plant and a portion of the heating fluid,a fourth hydrocracking plant heat exchanger in the third heating fluid circuit exchanges heat between a hydrocracking main fractionator overhead stream in the hydrocracking plant and a portion of the heating fluid,a fifth hydrocracking plant heat exchanger in the third heating fluid circuit exchanges heat between a hydrocracking main fractionator diesel product stream in the hydrocracking plant and a portion of the heating fluid,a sixth hydrocracking plant heat exchanger in the third heating fluid circuit exchanges heat between a hydrocracking main fractionator kerosene pumparound stream in the hydrocracking plant and a portion of the heating fluid, anda seventh hydrocracking plant heat exchanger in the third heating fluid circuit exchanges heat between a hydrocracking main fractionator kerosene stream in the hydrocracking plant and a portion of the heating fluid. 10. The system of claim 9, wherein: a first diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit exchanges heat between a light effluent to cold separator stream in the diesel hydro-treating plant and a portion of the heating fluid,a second diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit exchanges heat between a diesel stripper overhead stream in the diesel hydro-treating plant and a portion of the heating fluid, anda third diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit exchanges heat between a diesel stripper product stream in the diesel hydro-treating plant and a portion of the heating fluid. 11. The system of claim 1, wherein the heating fluid circuit comprises water or oil. 12. The system of claim 1, wherein the power generation system is on-site at the petrochemical refining system. 13. The system of claim 1, wherein the power generation system is configured to generate about 69 MW of power. 14. A method of recovering heat energy generated by a petrochemical refining system, the method comprising: identifying a geographic layout to arrange a plurality of sub-units of a petrochemical refining system, the geographic layout including a plurality of sub-unit locations at which the respective plurality of sub-units are to be positioned, wherein the plurality of sub-units comprises a hydrocracking plant, an aromatics plant and a diesel hydro-treating plant;identifying a first subset of the plurality of sub-units of the petrochemical refining system, the first subset including a plurality of hydrocracking plant heat exchangers coupled to streams in the hydrocracking plant, a plurality of aromatics plant heat exchangers coupled to streams in the aromatics plant, and a plurality of diesel hydro-treating plant heat exchangers coupled to streams in the diesel hydro-treating plant, wherein heat energy is recoverable from the first subset to generate electrical power;identifying, in the geographic layout, a second subset of the plurality of sub-unit locations, the second subset including sub-unit locations at which the respective sub-units in the first subset are to be positioned;identifying a first power generation system, a second power generation system, and a third power generation system comprising a first organic Rankine cycle (ORC), a second ORC and a third ORC, respectively, the first ORC comprising (i) a first working fluid that is thermally coupled to the first heating fluid circuit and the second heating fluid circuit to heat the first working fluid, and (ii) a first expander configured to generate electrical power from the heated first working fluid,the second ORC comprising (i) a second working fluid that is thermally coupled to the third heating fluid circuit to heat the second working fluid, and (ii) a second expander configured to generate electrical power from the heated second working fluid, andthe third ORC comprising (i) a third working fluid that is thermally coupled to the fourth heating fluid circuit, and (ii) a third expander configured to generate electrical power from the heated third working fluid, anda control system configured to activate a set of control valves to selectively thermally couple each of the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit and the fourth heating fluid circuit to at least a portion of the plurality of heat sources; andidentifying, in the geographic layout, a power generation system location to position each of the first power generation system, the second power generation system, and the third 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. 15. The method of claim 14, 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 each of the first power generation system, the second power generation system, and the third power generation system at the respective 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 each power generation system with the sub-units in the first subset such that each 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 each power generation system, each power generation system configured to generate power using the recovered heat energy. 16. The method of 15, further comprising: operating the petrochemical refining system to refine petrochemicals; andoperating the first power generation system, the second power generation system, and the third power generation system to: recover heat energy from the sub-units in the first subset through the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit, and the fourth heating fluid circuit;provide the recovered heat energy to the first power generation system, the second power generation system, and the third power generation system; andgenerate power using the recovered heat energy. 17. The method of claim 16, further comprising: thermally coupling the first working fluid to the first heating fluid circuit in a first pre-heater of the first ORC and to the second heating fluid circuit in a first evaporator of the first ORC,thermally coupling the second working fluid to the second heating fluid circuit in a second evaporator of the second ORC, andthermally coupling the third working fluid to the third heating fluid circuit in a third evaporator of the third ORC. 18. The method of claim 16, wherein each aromatics plant heat exchanger comprises a respective stream circulated through the aromatics plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between an extract column overhead stream in a para-xylene separation unit in the aromatics plant and a portion of the heating fluid,operating a second aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a PX purification column bottom product stream in the para-xylene separation unit and a portion of the heating fluid,operating a third aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a heavy Raffinate column splitter in the aromatics plant and a portion of the heating fluid,operating a fourth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Raffinate splitter column overhead stream in the aromatics plant and a portion of the heating fluid,operating a fifth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Xylene isomerization reactor outlet stream in the aromatics plant and a portion of the heating fluid,operating a sixth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a de-heptanizer column overhead stream in a xylene isomerization de-heptanizer in the aromatics plant and a portion of the heating fluid,operating a seventh aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a benzene column overhead stream in an aromatics benzene extraction unit in the aromatics plant and a portion of the heating fluid,operating an eighth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between an extractive distillation column overhead stream in an aromatics complex extractive distillation column unit in the aromatics plant and a portion of the heating fluid, andoperating a ninth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Raffinate splitter overhead stream in an aromatics complex raffinate splitter in the aromatics plant and a portion of the heating fluid. 19. The method of claim 18, wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first aromatics plant heat exchanger in the second heating fluid circuit to exchange heat between a PX purification column overhead stream in the aromatics plant and a portion of the heating fluid, andoperating a second aromatics plant heat exchanger in the second heating fluid circuit to exchange heat between a Raffinate column overhead stream in the aromatics plant and a portion of the heating fluid. 20. The method of claim 19, wherein each hydrocracking plant heat exchanger comprises a respective stream circulated through the hydrocracking plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a 2nd stage reaction section feed stream to 2nd stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,operating a second hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a 1st stage reaction section feed stream to 1st stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,operating a third hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a hydrocracking product stripper overhead stream in the hydrocracking plant and a portion of the heating fluid,operating a fourth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator overhead stream in the hydrocracking plant and a portion of the heating fluid,operating a fifth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator diesel product stream in the hydrocracking plant and a portion of the heating fluid,operating a sixth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator kerosene pumparound stream in the hydrocracking plant and a portion of the heating fluid, andoperating a seventh hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator kerosene stream in the hydrocracking plant and a portion of the heating fluid. 21. The method of claim 20, wherein each diesel hydro-treating plant heat exchanger comprises a respective stream circulated through the diesel hydro-treating plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a light effluent to cold separator stream in the diesel hydro-treating plant and a portion of the heating fluid,operating a second diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a diesel stripper overhead stream in the diesel hydro-treating plant and a portion of the heating fluid, andoperating a third diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a diesel stripper product stream in the diesel hydro-treating plant and a portion of the heating fluid. 22. The method of claim 14, further comprising operating the first power generation system, the second power generation system, and the third power generation system to generate about 69 MW of power. 23. A method of re-using heat energy generated by an operational petrochemical refining system, the method comprising: identifying a geographic layout that comprises an arrangement of a plurality of sub-units of an operational petrochemical refining system, the geographic layout including a plurality of sub-units, each positioned at a respective sub-unit location;identifying a first subset of the plurality of sub-units of the petrochemical refining system, the first subset including a plurality of aromatics plant heat exchangers coupled to streams in the aromatics plant, a plurality of hydrocracking plant heat exchangers coupled to streams in the hydrocracking plant, and a plurality of diesel hydro-treating plant heat exchangers coupled to streams in the diesel hydro-treating plant, wherein heat energy is recoverable from the first subset to generate electrical power;identifying, in the geographic layout, a second subset of the plurality of sub-unit locations, the second subset including sub-unit locations at which the respective sub-units in the first subset have been positioned;identifying a first power generation system, a second power generation system, and a third power generation system comprising a first organic Rankine cycle (ORC), a second ORC and a third ORC, respectively, the first ORC comprising (i) a first working fluid that is thermally coupled to the first heating fluid circuit and the second heating fluid circuit to heat the first working fluid, and (ii) a first expander configured to generate electrical power from the heated first working fluid,the second ORC comprising (i) a second working fluid that is thermally coupled to the third heating fluid circuit to heat the second working fluid, and (ii) a second expander configured to generate electrical power from the heated second working fluid, andthe third ORC comprising (i) a third working fluid that is thermally coupled to the fourth heating fluid circuit, and (ii) a third expander configured to generate electrical power from the heated third working fluid, anda control system configured to activate a set of control valves to selectively thermally couple each of the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit and the fourth heating fluid circuit to at least a portion of the plurality of heat sources; andidentifying, in the geographic layout, a power generation system location to position each of the first power generation system, the second power generation system, and the third 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. 24. The method of claim 23, further comprising interconnecting the first power generation system, the second power generation system, and the third power generation system with the sub-units in the first subset through the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit and the fourth heating fluid circuit 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 first power generation system, the second power generation system, and the third power generation system, the first power generation system, the second power generation system, and the third power generation system configured to generate power using the recovered heat energy. 25. The method of claim 23, further comprising operating the power generation system to: recover heat energy from the sub-units in the first subset through the first heating fluid circuit, the second heating fluid circuit, the third heating fluid circuit, and the fourth heating fluid circuit;provide the recovered heat energy to the first power generation system, the second power generation system, and the third power generation system; andgenerate power using the recovered heat energy. 26. The method of claim 23, wherein each aromatics plant heat exchanger comprises a respective stream circulated through the aromatics plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between an extract column overhead stream in a para-xylene separation unit in the aromatics plant and a portion of the heating fluid,operating a second aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a PX purification column bottom product stream in the para-xylene separation unit and a portion of the heating fluid,operating a third aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a heavy Raffinate column splitter in the aromatics plant and a portion of the heating fluid,operating a fourth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Raffinate splitter column overhead stream in the aromatics plant and a portion of the heating fluid,operating a fifth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Xylene isomerization reactor outlet stream in the aromatics plant and a portion of the heating fluid,operating a sixth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a de-heptanizer column overhead stream in a xylene isomerization de-heptanizer in the aromatics plant and a portion of the heating fluid,operating a seventh aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a benzene column overhead stream in an aromatics benzene extraction unit in the aromatics plant and a portion of the heating fluid,operating an eighth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between an extractive distillation column overhead stream in an aromatics complex extractive distillation column unit in the aromatics plant and a portion of the heating fluid, andoperating a ninth aromatics plant heat exchanger in the first heating fluid circuit to exchange heat between a Raffinate splitter overhead stream in an aromatics complex raffinate splitter in the aromatics plant and a portion of the heating fluid. 27. The method of claim 26, wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first aromatics plant heat exchanger in the second heating fluid circuit to exchange heat between a PX purification column overhead stream in the aromatics plant and a portion of the heating fluid, andoperating a second aromatics plant heat exchanger in the second heating fluid circuit to exchange heat between a Raffinate column overhead stream in the aromatics plant and a portion of the heating fluid. 28. The method of claim 27, wherein each hydrocracking plant heat exchanger comprises a respective stream circulated through the hydrocracking plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a 2nd stage reaction section feed stream to 2nd stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,operating a second hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a 1st stage reaction section feed stream to 1st stage cold high pressure separator in the hydrocracking plant and a portion of the heating fluid,operating a third hydrocracking plant heat exchanger in third heating fluid circuit to exchange heat between a hydrocracking product stripper overhead stream in the hydrocracking plant and a portion of the heating fluid,operating a fourth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator overhead stream in the hydrocracking plant and a portion of the heating fluid,operating a fifth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator diesel product stream in the hydrocracking plant and a portion of the heating fluid,operating a sixth hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator kerosene pumparound stream in the hydrocracking plant and a portion of the heating fluid, andoperating a seventh hydrocracking plant heat exchanger in the third heating fluid circuit to exchange heat between a hydrocracking main fractionator kerosene stream in the hydrocracking plant and a portion of the heating fluid. 29. The method of claim 28, wherein each diesel hydro-treating plant heat exchanger comprises a respective stream circulated through the diesel hydro-treating plant and a portion of the heating fluid, and wherein operating the first power generation system, the second power generation system, and the third power generation system comprises: operating a first diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a light effluent to cold separator stream in the diesel hydro-treating plant and a portion of the heating fluid,operating a second diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a diesel stripper overhead stream in the diesel hydro-treating plant and a portion of the heating fluid, andoperating a third diesel hydro-treating plant heat exchanger in the fourth heating fluid circuit to exchange heat between a diesel stripper product stream in the diesel hydro-treating plant and a portion of the heating fluid. 30. The method of claim 29, further comprising operating the first power generation system, the second power generation system, and the third power generation system to generate about 69 MW of power.
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