Proposal and analysis of a coupled power generation system for natural gas pressure reduction stations

Cheng-hao Li; Si-yang Zheng; Xing-yu Chen; Jie Li; Zhi-yong Zeng

doi:10.1007/s11771-020-4320-3

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (2) : 608 -620. DOI: 10.1007/s11771-020-4320-3

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Proposal and analysis of a coupled power generation system for natural gas pressure reduction stations

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Abstract

With the increased use of natural gas, it is valuable to study energy recovery ratio in the natural gas pressure reduction stations (PRSs). This paper focused on recovering the energy in PRSs as well as low-grade waste heat by a coupled power generation system (CPGS). The CPGS integrates a natural gas expansion (NGE) subsystem and an organic Rankine cycle (ORC) subsystem driven by low-temperature waste heat. Firstly, a comparative analysis is carried out between the separated natural gas expansion system and the separated ORC system. Then, the effects of heat source conditions, upstream pressure of natural gas and the isentropic efficiency of the natural gas expander are investigated. At last, working fluids selection is conducted with respect to two different pressure ranges of natural gas. The results show that there is an optimal temperature and mass flow rate of the heat source that maximizes the system exergy efficiency. With the increase of the upstream pressure of natural gas, the net power output and waste heat recovery factor increase while the system exergy efficiency has an optimal point. Furthermore, the isentropic efficiency of the natural gas expander has a great influence on the net power output of the system.

Keywords

natural gas / energy recovery / organic Rankine cycle (ORC) / working fluids selection

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Cheng-hao Li, Si-yang Zheng, Xing-yu Chen, Jie Li, Zhi-yong Zeng. Proposal and analysis of a coupled power generation system for natural gas pressure reduction stations. Journal of Central South University, 2020, 27(2): 608-620 DOI:10.1007/s11771-020-4320-3

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References

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[1]	Lo, CascioE, BorelliD, DeviaF, SchenoneC. Key performance indicators for integrated natural gas pressure reduction stations with energy recovery. Energy Conversion and Management, 2018, 164: 219-229

[2]	LI C H, LIU J W, ZHENG S Y, CHEN X Y, LI J, ZENG Z Y. Performance analysis of an improved power generation system utilizing the cold energy of LNG and solar energy [J]. Applied Thermal Engineering, 2019, 159: 113937. DOI: 10.1016/j.applthermaleng.2019. 113937.

[3]	LiP C, LiJ, PeiG, MunirA, JiJ A. cascade organic Rankine cycle power generation system using hybrid solar energy and liquefied natural gas. Solar Energy, 2016, 127: 136-146

[4]	YaoS, ZhangY F, DengN, YuX H, DongS M. Performance research on a power generation system using twin-screw expanders for energy recovery at natural gas pressure reduction stations under off-design conditions. Applied Energy, 2019, 236: 1218-1230

[5]	TanH B, ZhaoQ X, SunN N, LiY Z. Proposal and design of a natural gas liquefaction process recovering the energy obtained from the pressure reducing stations of high-pressure pipelines. Cryogenics, 2016, 80: 82-90

[6]	Farzaneh, GordM, JannatabadiM. Simulation of single acting natural gas Reciprocating Expansion Engine based on ideal gas model. Journal of Natural Gas Science and Engineering, 2014, 21: 669-679

[7]	AshouriE, VeysiF, ShojaeizadehE, AsadiM. The minimum gas temperature at the inlet of regulators in natural gas pressure reduction stations (CGS) for energy saving in water bath heaters. Journal of Natural Gas Science and Engineering, 2014, 21: 230-240

[8]	OlfatiM, BahiraeiM, HeidariS, VeysiF. A comprehensive analysis of energy and exergy characteristics for a natural gas city gate station considering seasonal variations. Energy, 2018, 155: 721-733

[9]	PozivilJ. Use of expansion turbines in natural gas pressure reduction stations. Acta Montanistica Slovaca, 2004, 9(3): 258-260

[10]	NeseliM A, OzgenerO, OzgenerL. Energy and exergy analysis of electricity generation from natural gas pressure reducing stations. Energy Conversion and Management, 2015, 93: 109-120

[11]	HowardC, OosthuizenP, PeppleyB. An investigation of the performance of a hybrid turboexpanderfuel cell system for power recovery at natural gas pressure reduction stations. Applied Thermal Engineering, 2011, 31(13): 2165-2170

[12]	KostowskiW J U S. Comparative evaluation of a natural gas expansion plant integrated with an IC engine and an organic Rankine cycle. Energy Conversion and Management, 2013, 75: 509-516

[13]	Saadat-TarghiM, KhanmohammadiS. Energy and exergy analysis and multi-criteria optimization of an integrated city gate station with organic Rankine flash cycle and thermoelectric generator. Applied Thermal Engineering, 2019, 149: 312-324

[14]	SanayeS, Mohammadi NasabA. Modeling and optimizing a CHP system for natural gas pressure reduction plant. Energy, 2012, 40(1): 358-369

[15]	Farzaneh-GordM, ArabkoohsarA, DashtbayazM D, Farzaneh-KordV. Feasibility of accompanying uncontrolled linear heater with solar system in natural gas pressure drop stations. Energy, 2012, 41(1): 420-428

[16]	CascioE L, MaZ, SchenoneC. Performance assessment of a novel natural gas pressure reduction station equipped with parabolic trough solar collectors. Renewable Energy, 2018, 128: 177-187

[17]	Farzaneh-GordM, GhezelbashR, ArabkoohsarA, PilevariL, MachadoL, KouryR N N. Employing geothermal heat exchanger in natural gas pressure drop station in order to decrease fuel consumption. Energy, 2015, 83: 164-176

[18]	ArabkoohsarA, GharahchomaghlooZ F-, GordM, KouryR N N, DeymidashtebayaM. An energetic and economic analysis of power productive gas expansion stations for employing combined heat and power. Energy, 2017, 133: 737-748

[19]	BorelliD, DeviaF, Lo, CascioE, SchenoneC. Energy recovery from natural gas pressure reduction stations: Integration with low temperature heat sources. Energy Conversion and Management, 2018, 159: 274-283

[20]	Alparslan, NeseliM, OzgenerO, OzgenerL. Thermo-mechanical exergy analysis of Marmara Eregli natural gas pressure reduction station (PRS): An application. Renewable and Sustainable Energy Reviews, 2017, 77: 80-88

[21]	KostowskiW J, UsónS. Thermoeconomic assessment of a natural gas expansion system integrated with a co-generation unit. Applied Energy, 2013, 101: 58-66

[22]	CuiP Z, YuM X, LiuZ Q, ZhuZ Y, YangS. Energy, exergy, and economic (3E) analyses and multi-objective optimization of a cascade absorption refrigeration system for low-grade waste heat recovery. Energy Conversion and Management, 2019, 184: 249-261

[23]	YuH, GundersenT, FengX. Process integration of organic Rankine cycle (ORC) and heat pump for low temperature waste heat recovery. Energy, 2018, 160: 330-340

[24]	MondejarM E, AhlgrenF, ThernM, GenrupM. Quasi-steady state simulation of an organic Rankine cycle for waste heat recovery in a passenger vessel. Applied Energy, 2017, 185: 1324-1335

[25]	KhalilzadehS, Hossein, NezhadA. Utilization of waste heat of a high-capacity wind turbine in multi effect distillation desalination: Energy, exergy and thermoeconomic analysis. Desalination, 2018, 439: 119-137

[26]	YangS, YangS Y, WangY F, QianY. Low grade waste heat recovery with a novel cascade absorption heat transformer. Energy, 2017, 130: 461-472

[27]	UusitaloA, HonkatukiaJ T-, SaarestiT, LarjolaJ. A thermodynamic analysis of waste heat recovery from reciprocating engine power plants by means of organic Rankine cycles. Applied Thermal Engineering, 2014, 70(1): 33-41

[28]	LiC H, ZhengS Y, LiJ, ZengZ Y. Optimal design and thermo-economic analysis of an integrated power generation system in natural gas pressure reduction stations. Energy Conversion and Management, 2019, 200112079