涡轮级间燃烧室内混合与燃烧特性数值研究OA
Numerical study on mixing and combustion characteristics in an inter-stage turbine combustor
针对涡轮级间燃烧室内燃料/空气混合与燃烧特性展开数值研究,本文重点探讨喷注方式对混合机理的影响规律及燃烧过程的控制机制.通过引入宏观与微观混合概念,结合ANSYS Fluent软件建立数值模型,采用火焰生成流形模型模拟湍流燃烧过程,并利用输运方程分析燃料在凹腔回流区的驻留时间特性.通过对比 4 种不同喷注方案(前壁、顶壁、后壁及耦合喷注)对混合效率、燃烧效率及火焰稳定性的影响,发现:喷注方式显著改变燃料在凹腔回流区的驻留时间,其中后壁喷注(方案三)的燃料驻留时间最长(达 4 ms以上),有利于火焰稳定;混合过程主要由对流主导的宏观混合决定,而微观混合受湍流脉动影响显著.在补燃区出口下游 20 mm处,方案三的综合混合效率达 98.5%,而其他方案在同一位置仅为 92%~94%.燃烧性能方面,方案三在燃烧室出口处的综合燃烧效率达 95.1%,较方案一(93.2%)、方案二(92.8%)和方案四(94.0%)更高,进一步验证了后壁喷注在整体燃烧性能上的优势.燃烧模式以扩散火焰为主,但强湍流导致局部熄火与再燃现象,呈现部分预混特性.凹腔回流区通过高温产物对可燃气体持续强迫点火实现火焰稳定,而燃料主要氧化释热过程发生在凹腔外主流通道.
This study conducts a numerical investigation on fuel/air mixing and combustion characteristics in an inter-turbine combustor,with a focus on elucidating the influence mechanisms of fuel injection schemes on mixing dynamics and combustion control strategies.By introducing macro-and micro-mixing concepts,a numerical model is established using ANSYS Fluent software,where the FGM(Flamelet Generated Manifold)method is employed to simulate turbulent combustion processes.Transport equation analysis is implemented to characterize fuel residence time properties in the cavity recirculation zone.Four distinct fuel injection configurations(front-wall,top-wall,rear-wall,and coupled injection schemes)are systematically designed and compared regarding their effects on mixing efficiency,combustion efficiency,and flame stability.Results demonstrate that injection schemes significantly alter fuel residence time in the cavity recirculation zone,with rear-wall injection(Scheme 3)achieving the longest residence time(exceeding 4 ms),which enhances flame stabilization.The mixing process is predominantly governed by convection-dominated macro-mixing,while micro-mixing shows significant dependence on turbulent fluctuations.At a position 20 mm downstream of the afterburning zone outlet,the comprehensive mixing efficiency of Scheme 3 reached 98.5%,while that of other schemes at the same location was only 92%-94%.In terms of combustion performance,the overall combustion efficiency of Scheme 3 at the combustor outlet reached 95.1%,which is higher than that of Scheme 1(93.2%),Scheme 2(92.8%),and Scheme 4(94.0%),further validating the advantage of its rear-wall injection in overall combustion performance.The combustion regime primarily follows diffusion flame characteristics,but strong turbulence induces local extinction and re-ignition phenomena,exhibiting partially premixed features.The cavity recirculation zone maintains flame stability through sustained forced ignition of combustible gases by high-temperature products,while the primary fuel oxidation and heat release processes occur in the mainstream channel outside the cavity.These findings provide theoretical foundations for optimizing fuel injection strategies and combustion organization design in inter-stage combustors.
杜钊;郝颜;龚诚;周瑜;江平
中国空气动力研究与发展中心 空天技术研究所,绵阳 621000||南昌航空大学 动力与能源学院,南昌 330063中国空气动力研究与发展中心 空天技术研究所,绵阳 621000中国空气动力研究与发展中心 空天技术研究所,绵阳 621000中国空气动力研究与发展中心 空天技术研究所,绵阳 621000南昌航空大学 动力与能源学院,南昌 330063
航空航天
涡轮级间燃烧室喷注方式混合效率燃烧效率火焰稳定性
turbine inter-stage combustorinjection methodmixing efficiencycombusiton efficiencyflame stability
《空气动力学学报》 2026 (3)
44-56,13
中国空气动力研究与发展中心基础和前沿技术研究基金资助项目(PJD20170176)江西省研究生创新专项资金项目(YC2023-S728)
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