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模型燃气轮机燃烧室多孔燃烧器上稳定的高共稀释氧丙烷火焰分析

Analysis of Highly CO-Diluted Oxy-propane Flames Stabilized over a Multihole Burner of a Model Gas Turbine Combustor.

作者信息

Habib Mohamed A, Haque Md Azazul, Nemitallah Medhat A, Abdelhafez Ahmed, Khalifa Atia E

机构信息

Interdisciplinary Research Center for Hydrogen & Energy Storage (IRC-HES), King Fahd University of Petroleum and Minerals, Dhahran31261, Saudi Arabia.

Researcher at K.A. CARE Energy Research & Innovation Center at Dhahran, Riyadh11451, Saudi Arabia.

出版信息

ACS Omega. 2022 Nov 3;7(45):41493-41507. doi: 10.1021/acsomega.2c05274. eCollection 2022 Nov 15.

DOI:10.1021/acsomega.2c05274
PMID:36406490
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9670281/
Abstract

Premixed oxy-propane flames are investigated numerically in a multihole model gas turbine combustor at various inlet mixture compositions over a range of equivalence ratios (Ø: 0.241-0.500), oxygen fractions (OF: 32.4-60.0%), and adiabatic flame temperatures ( : 1600-1900 K) at a constant bulk throat velocity of 5.2 m/s. The flames in multihole combustors are highly influenced by their corresponding adiabatic flame temperatures. Similar flame shapes are observed at constant , where cases with (Ø = 0.241, OF = 60%) and (Ø = 0.50, OF = 32.4%) both represent lifted flames at = 1600 K, anchored flames in (Ø = 0.276, OF = 60%) and (Ø = 0.50, OF = 36.6%) at = 1750 K, and anchored stronger flames in cases (Ø = 0.313, OF = 60%), (Ø = 0.392, OF = 50%), and (Ø = 0.50, OF = 40.8%) at = 1900 K. Flames in a multihole combustor are characterized by the presence of an outer recirculation zone (ORZ) only. In comparison with a swirl-stabilized combustor in identical inlet conditions, flames in a multihole combustor demonstrate a lower Damköhler number (), higher flame thickness, elevated pattern factor, and increased CO emission. Due to the reduced vorticity level because of the absence of swirl motion, the multihole flames have higher axial temperature than the swirl-stabilized ones.

摘要

在一个多孔模型燃气轮机燃烧室中,对预混氧丙烷火焰进行了数值研究。研究工况为不同的入口混合物成分,当量比范围为Ø:0.241 - 0.500,氧分数范围为OF:32.4 - 60.0%,绝热火焰温度范围为:1600 - 1900 K,且保持恒定的整体喉部速度为5.2 m/s。多孔燃烧室中的火焰受其相应绝热火焰温度的影响很大。在恒定 时观察到类似的火焰形状,其中(Ø = 0.241,OF = 60%)和(Ø = 0.50,OF = 32.4%)的工况在 = 1600 K时均表现为抬升火焰,(Ø = 0.276,OF = 60%)和(Ø = 0.50,OF = 36.6%)的工况在 = 1750 K时为附着火焰,而(Ø = 0.313,OF = 60%)、(Ø = 0.392,OF = 50%)和(Ø = 0.50,OF = 40.8%)的工况在 = 1900 K时为更强的附着火焰。多孔燃烧室中的火焰仅以外回流区(ORZ)的存在为特征。与相同入口条件下的旋流稳定燃烧室相比,多孔燃烧室中的火焰具有更低的达姆科勒数()、更高的火焰厚度、更高的图案因子和更高的CO排放。由于没有旋流运动导致涡度水平降低,多孔火焰的轴向温度比旋流稳定火焰更高。

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