Helicopter turboshaft engines combustion chamber monitoring neural network method

IF 5.2 2区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Measurement Pub Date : 2024-11-20 DOI:10.1016/j.measurement.2024.116267

Serhii Vladov , Maryna Bulakh , Denys Baranovskyi , Valerii Sokurenko , Oleksandr Muzychuk , Victoria Vysotska

{"title":"Helicopter turboshaft engines combustion chamber monitoring neural network method","authors":"Serhii Vladov , Maryna Bulakh , Denys Baranovskyi , Valerii Sokurenko , Oleksandr Muzychuk , Victoria Vysotska","doi":"10.1016/j.measurement.2024.116267","DOIUrl":null,"url":null,"abstract":"<div><div>The article proposes an innovative method for helicopter turboshaft engines’ combustion chamber monitoring based on a neural network, significantly impacting the aircraft engines’ diagnostics and monitoring subject area. This article’s main contribution is to improve defect detections’ accuracy and timeliness, which in turn contributes to the aircraft equipment operations’ reliability and safety. The developed method, leveraging an enhanced adaptive neuro-fuzzy inference system (ANFIS) neuro-fuzzy network with Sugeno-Takagi inference, significantly improves defect detection accuracy and reduces diagnostic errors, thereby enhancing the reliability and safety of flight operations. To implement it, the combustion chamber mathematical model was created based on the heat balance equation, which showed that the fuel combustion completeness coefficient is a diagnostic criterion for defects. It is mathematically substantiated that this coefficient determines combustion efficiency and directly affects thermal energy. The ANFIS with Sugeno-Takagi fuzzy inference architecture has been improved, making it possible to achieve the defects diagnosis and prediction accuracy of 99.65 %. The ANFIS neuro-fuzzy network with Sugeno-Takagi inference proposed in this work improves quality metrics for determining helicopter turboshaft engines’ combustion chamber defects, enhancing the fuel combustion completeness coefficient by 1.01 to 4.64 times. Experimental results show that optimal network training with a loss of 0.35 % is achieved in 60 epochs, which is 2.0 to 9.5 times faster than traditional algorithms (genetic algorithm, traditional backpropagation algorithm, traditional inverse gradient descending method, modified inverse gradient descending method, hybrid algorithm). The absence of hidden T-patterns in the fuel combustion completeness coefficient dynamics (the value does not exceed 10<sup>–4</sup>) is also substantiated, confirming the proposed method’s high accuracy. The accumulated heat experimental surfaces’ dependences on the dynamics and fuel consumption were obtained, which makes it possible to analyze the defects’ influence on the combustion chamber’s thermal characteristics. The proposed ANFIS network use reduces the 1st and 2nd types’ errors by 1.44…6.15 times when determining combustion chamber defects compared to other architectures and classical methods, such as the least squares method.</div></div>","PeriodicalId":18349,"journal":{"name":"Measurement","volume":"242 ","pages":"Article 116267"},"PeriodicalIF":5.2000,"publicationDate":"2024-11-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Measurement","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0263224124021523","RegionNum":2,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENGINEERING, MULTIDISCIPLINARY","Score":null,"Total":0}

引用次数: 0

Abstract

The article proposes an innovative method for helicopter turboshaft engines’ combustion chamber monitoring based on a neural network, significantly impacting the aircraft engines’ diagnostics and monitoring subject area. This article’s main contribution is to improve defect detections’ accuracy and timeliness, which in turn contributes to the aircraft equipment operations’ reliability and safety. The developed method, leveraging an enhanced adaptive neuro-fuzzy inference system (ANFIS) neuro-fuzzy network with Sugeno-Takagi inference, significantly improves defect detection accuracy and reduces diagnostic errors, thereby enhancing the reliability and safety of flight operations. To implement it, the combustion chamber mathematical model was created based on the heat balance equation, which showed that the fuel combustion completeness coefficient is a diagnostic criterion for defects. It is mathematically substantiated that this coefficient determines combustion efficiency and directly affects thermal energy. The ANFIS with Sugeno-Takagi fuzzy inference architecture has been improved, making it possible to achieve the defects diagnosis and prediction accuracy of 99.65 %. The ANFIS neuro-fuzzy network with Sugeno-Takagi inference proposed in this work improves quality metrics for determining helicopter turboshaft engines’ combustion chamber defects, enhancing the fuel combustion completeness coefficient by 1.01 to 4.64 times. Experimental results show that optimal network training with a loss of 0.35 % is achieved in 60 epochs, which is 2.0 to 9.5 times faster than traditional algorithms (genetic algorithm, traditional backpropagation algorithm, traditional inverse gradient descending method, modified inverse gradient descending method, hybrid algorithm). The absence of hidden T-patterns in the fuel combustion completeness coefficient dynamics (the value does not exceed 10^–4) is also substantiated, confirming the proposed method’s high accuracy. The accumulated heat experimental surfaces’ dependences on the dynamics and fuel consumption were obtained, which makes it possible to analyze the defects’ influence on the combustion chamber’s thermal characteristics. The proposed ANFIS network use reduces the 1st and 2nd types’ errors by 1.44…6.15 times when determining combustion chamber defects compared to other architectures and classical methods, such as the least squares method.

查看原文本刊更多论文

直升机涡轮轴发动机燃烧室监测神经网络方法

文章提出了一种基于神经网络的直升机涡轮轴发动机燃烧室监测创新方法，对飞机发动机诊断和监测领域产生了重大影响。本文的主要贡献在于提高缺陷检测的准确性和及时性，进而提高飞机设备运行的可靠性和安全性。所开发的方法利用具有 Sugeno-Takagi 推理功能的增强型自适应神经模糊推理系统（ANFIS）神经模糊网络，显著提高了缺陷检测的准确性，减少了诊断误差，从而提高了飞行运行的可靠性和安全性。为了实施该系统，根据热平衡方程建立了燃烧室数学模型，结果表明燃料燃烧完全系数是缺陷的诊断标准。数学证明，该系数决定燃烧效率并直接影响热能。改进了具有 Sugeno-Takagi 模糊推理结构的 ANFIS，使缺陷诊断和预测准确率达到 99.65 %。本研究提出的带 Sugeno-Takagi 推理的 ANFIS 神经模糊网络改善了直升机涡轮轴发动机燃烧室缺陷的质量指标，将燃料燃烧完整性系数提高了 1.01 至 4.64 倍。实验结果表明，在损失为 0.35 % 的情况下，60 个 epoch 就能实现最佳网络训练，比传统算法（遗传算法、传统反向传播算法、传统反梯度下降法、改进的反梯度下降法、混合算法）快 2.0 到 9.5 倍。燃料燃烧完全系数动态变化中不存在隐藏的 T 型（数值不超过 10-4），这也证实了所提出方法的高准确性。此外，还获得了累积热实验面对动力学和燃料消耗量的依赖关系，这使得分析缺陷对燃烧室热特性的影响成为可能。在确定燃烧室缺陷时，与其他结构和经典方法（如最小二乘法）相比，所提议的 ANFIS 网络可将第一类和第二类误差减少 1.44...6.15 倍。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Measurement 工程技术-工程：综合

CiteScore

10.20

自引率

12.50%

发文量

1589

审稿时长

12.1 months

期刊介绍： Contributions are invited on novel achievements in all fields of measurement and instrumentation science and technology. Authors are encouraged to submit novel material, whose ultimate goal is an advancement in the state of the art of: measurement and metrology fundamentals, sensors, measurement instruments, measurement and estimation techniques, measurement data processing and fusion algorithms, evaluation procedures and methodologies for plants and industrial processes, performance analysis of systems, processes and algorithms, mathematical models for measurement-oriented purposes, distributed measurement systems in a connected world.