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基于丁烷工质和高沸点苯基萘液体加热系统的有机朗肯循环的大涡模拟与热力设计

Large Eddy Simulation and Thermodynamic Design of the Organic Rankine Cycle Based on Butane Working Fluid and the High-Boiling-Point Phenyl Naphthalene Liquid Heating System.

作者信息

Davidy Alon

机构信息

Independent Research Scientist, Petach Tiqwa 4942136, Israel.

出版信息

Entropy (Basel). 2022 Oct 13;24(10):1461. doi: 10.3390/e24101461.

DOI:10.3390/e24101461
PMID:37420481
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9602139/
Abstract

Large Eddy Simulation (LES) and Thermodynamic study have been performed on Organic Rankine Cycle (ORC) components (boiler, evaporator, turbine, pump, and condenser). The petroleum Coke burner provided the heat flux needed for the butane evaporator. High boiling point fluid (called phenyl-naphthalene) has been applied in the ORC. The high boiling liquid is safer (steam explosion hazard may be prevented) for heating the butane stream. It has best exergy efficiency. It is non-corrosive, highly stable, and flammable. Fire Dynamics Simulator software (FDS) has been applied in order to simulate the pet-coke combustion and calculate the Heat Release Rate (HRR). The maximal temperature of the 2-Phenylnaphthalene flowing in the boiler is much less than its boiling temperature (600 K). Enthalpy, entropy and specific volume required for evaluating the heat rates and the power have been computed by employing the THERMOPTIM thermodynamic code. The proposed design ORC is safer. This is because the flammable butane is separated from the flame produced in the petroleum coke burner. The proposed ORC obeys the two fundamental laws of thermodynamics. The calculated net power is 3260 kW. It is in good agreement with net power is reported in the literature. The thermal efficiency of the ORC is 18.0%.

摘要

已对有机朗肯循环(ORC)组件(锅炉、蒸发器、涡轮机、泵和冷凝器)进行了大涡模拟(LES)和热力学研究。石油焦燃烧器提供了丁烷蒸发器所需的热通量。高沸点流体(称为苯基萘)已应用于ORC中。高沸点液体用于加热丁烷流更安全(可防止蒸汽爆炸危险)。它具有最佳的火用效率。它无腐蚀性、高度稳定且易燃。已应用火灾动力学模拟器软件(FDS)来模拟石油焦燃烧并计算热释放率(HRR)。在锅炉中流动的2-苯基萘的最高温度远低于其沸点(600K)。通过使用THERMOPTIM热力学代码计算了评估热率和功率所需的焓、熵和比容。所提出的ORC设计更安全。这是因为易燃的丁烷与石油焦燃烧器中产生的火焰分隔开。所提出的ORC遵循热力学的两个基本定律。计算出的净功率为3260kW。这与文献中报道的净功率非常吻合。ORC的热效率为18.0%。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fb44/9602139/3889def6f6fb/entropy-24-01461-g014.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fb44/9602139/3889def6f6fb/entropy-24-01461-g014.jpg

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