关于热声不稳定性现象的一种控制方法

本文通过一个电加热镍铬丝作为热源的Rijke管实验装置,观察了电热丝在管中相对位置变化引起的不稳定发声声压级变化情况,并且研究了穿孔板加环形背腔这种结构对Rijke管不稳定发声的控制效果.通过实验可以发现,穿孔板的存在可以降低不稳定发声的强度,或者其不再发声而稳定.同时,证实了背腔中偏流的存在可以加强对热声不稳定的控制效果.     

基于气泵的声管实验及分析

为研究声管的发声频率，进行了实验设计和分析.声管转动发声是由于空气在声管中的流动，考虑实际的实验条件，设计了气泵吹气代替声管转动的实验方式，改变吹气速率并测量发声频率.通过对实验结果的分析发现，此时的声管不符合两端开口即两端为波腹的条件，而是一端波节、一端波腹.声管的发声频率取决于其长度，符合驻波特性，发声时吹气速率与波纹长度须满足共振条件.研究结果有助于对驻波的理解和相关内容的实验设计.     

演示用Sondhauss管的研制及理论分析

介绍了演示用 Sondhauss管的结构与制作过程 ,它具有直观、简单、成本低等突出优点 ,是一种比较理想的热声效应演示器件。通过初步实验 ,文中对热声管发声机制进行了理论分析 ,有助于更好地理解热声效应 ,并为进一步研究热声机理奠定了基础     

Rijke管热声非线性不稳定增长过程的研究

本文分析了Ｒｉｊｋｅ管热声不稳定性的非线性增长过程，通过流体力学中的三个基本守衡方程，得出了管内的声学量之间的关系，并通过采用热声相互作用的非线性关系式和管口声波的非线性反射条件，发展了一种可以计算出管内声波从小扰动增长到大振幅振动直到由于非线性效应的影响而停止增长的全过程的方法，最后实验验证了理论。     

传统笙的物理模型及声音合成方法

为研究传统笙的物理结构与音色之间的关系,提出了传统笙的物理模型及声音合成方法。在簧舌振动模型的基础上,结合指孔和音窗的传输矩阵计算方法,建立了笙管的等效电路,并将二者结合,得到笙的完整物理模型。为了验证模型的有效性,设计了一套笙的实验系统,实现了对笙管发声过程中特征量的多通道同步测量。通过对比实验和模型仿真结果的时频域特点以及与音色相关的特征量,分析了模型的性能.结果表明,该模型可较好地模拟传统笙管的发声过程,合成笙样本能够较准确的反映真实笙样本的音色特征。      

地埋管换热特性实验研究

使用恒温循环媒介,利用热平衡原理,建立了单U型管模拟实验装置,对埋管与岩土间的热传递进行了实验。实验表明,在距埋管较近的范围内,岩土层有较快的温度相应速率,而在较远的范围内,岩土层的温度相应速率较慢。通过埋管换热器传热性能实验,利用线热源模型得到了实验岩土的热导率。     

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对由埋管引起的面对等离子体第一壁热沉冷却结构冷却效果的下降进行了实验测量与数值模拟。在相同加热源条件下,比较了热沉内光孔、埋管打压胀管及高温真空埋管钎焊三种工艺实验件的换热效率,并与数值模拟的结果进行比较,确定了合理的计算模型和参数。对高场测的热沉原型件,比较了埋管打压胀管和高温真空钎焊连接换热效率,为EAST热沉冷却结构优化提供了依据。     

EAST装置第一壁热沉冷却结构关键工艺的研究

对由埋管引起的面对等离子体第一壁热沉冷却结构冷却效果的下降进行了实验测量与数值模拟。在相同加热源条件下,比较了热沉内光孔、埋管打压胀管及高温真空埋管钎焊三种工艺实验件的换热效率,并与数值模拟的结果进行比较,确定了合理的计算模型和参数。对高场测的热沉原型件,比较了埋管打压胀管和高温真空钎焊连接换热效率,为EAST热沉冷却结构优化提供了依据。     

双热源复合换热器复合换热温差影响因素分析

空气-水双热源复合换热器是太阳能-空气双热源复合热泵系统的核心部件,空气-水双热源复合换热器的有效复合换热温差对空气-水双热源复合换热器的换热性能以及太阳能-空气双热源复合热泵的系统性能具有重要影响。建立了空气-水双热源复合换热器和太阳能-空气双热源复合热泵系统的数学模型,利用数学模拟的方法研究了空气-水双热源复合换热器结构参数,即内外管径、翅片间距对有效复合换热温差的影响。模拟结果表明:空气-水双热源复合换热器的有效复合换热温差随内管管径的减小、外管管径的增大以及翅片间距的减小而增大。     

高温热管声速极限的实验研究与理论分析

高温热管是公认的被动式高温传热器件,以及明显高于相同几何尺寸金属材料的当量导热率,使其成为研究热点,并具有广泛的应用前景。在高温热管的蒸汽流动中,当喉部流速达到声速后,会出现声速传热极限,主要表现为冷凝段温度持续降低,传热量停滞不增,以及蒸汽的阻塞状态。本文设计、制备了高温热管传热器件,以高频感应方式为热源,盘管式水冷套为冷源,搭建了可以定量测试高温热管声速极限的实验台,并应用理论模型进行了验证。实验测试了高温热管在高热流加热条件下的冷态启动过程,以及稳态传热状态下的温度、热流等基本物理量,并对此进行了理论分析。实验结果表明:长径比、加热热流、工作温度是影响高温热管声速极限的主要因素。     

Reduced-order modelling of thermoacoustic instabilities in a two-heater Rijke tube

The topic of thermoacoustic instabilities in combustors is well-investigated, as it is important in the field of combustion, primarily in gas-turbine engines. In recent years, much attention has been focused on monitoring, diagnosis, prognosis, and control of high-amplitude pressure oscillations in confined combustion chambers. The Rijke tube is one of the most simple, yet very commonly used, laboratory apparatuses for emulation of thermoacoustic instabilities, which is also capable of capturing the physics of the thermally driven acoustics. A Rijke tube apparatus can be constructed with an electrical heater acting as the heat source, thus making it more flexible to operate and safer to handle than a fuel-burning Rijke tube or a fuel-fired combustor. Augmentation of the heat source of the Rijke tube with a secondary heater at a downstream location facilitates better control of thermoacoustic instabilities. Along this line, much work has been reported on the investigation of thermoacoustics by using computational fluid dynamics (CFD) modelling as well as reduced-order modelling for both single-heater and two-heater Rijke tube systems. However, since reduced-order models are often designed and built upon certain empirical relations, they may not account for the dynamic behaviour of the heater itself, which is a critical factor in the analysis and synthesis of real-time robust control systems. This issue is addressed in the current paper, where modifications have been made to existing models by incorporating heater dynamics. The model results are systematically validated with experimental data, generated from an in-house (electrically heated) Rijke tube apparatus.     

Investigation on Rijke pipe＇s acoustic characteristics by numerical simulation： modeling the pulsing flow field coupled the inner of pipe with its outer space

Based on the results of fluid dynamics, heat transfer and acoustics, a Computational Fluid Dynamics （CFD） method was utilized to study the acoustic characteristics and self-excited pulsation mechanism inside a Rijke pipe. To avoid settling the irrational boundary conditions of the finite-amplitude standing wave in the Rijke thermo-acoustic system, the simulation modeling in the flow field, which coupled the inner of pipe with its outer space, was carried out to replace the traditional way in form of internal flow field numerical investigations. A hypothesis for heat source in energy equation including the relationship on unsteady heat of air around heat source, oscillation pressure and oscillation velocity was presented. To reflect the essence of Rijke pipe, simulation on self-excited oscillation was conducted by means of its own pulsation of pressure, velocity and temperature. This method can make the convergence process steady and effectively avoid divergence. The physical phenomenon of the self-excited Rijke pipe was analyzed. Moreover, the mechanisms on the Rijke pipe＇s self-excited oscillation were explained. Based on this method, comparative researches on the acoustic characteristic of the Rijke pipe with different size and different shape of nozzle were performed. The simulation results agreed with the experimental data satisfactorily. The results show that this numerical simulation can be used to study the sound pressure of nozzle for the engineering application of Rijke pipes.     

黎开管热声振荡的主动控制研究

本文以黎开管内的热声耦合振荡为研究对象,设计基于主动补偿的适应性控制器抑制黎开管内的不稳定燃烧。试验以扬声器为执行机构来改变黎开管的边界条件,从而抑制黎开管内的热声耦合振荡。实时控制效果表明,本文所采用的适应性控制算法能够有效抑制因热声耦合产生的燃烧振荡,为实际动力系统燃烧振荡抑制提供了思路。     

Modular system for studying tonal sound excitation in resonators with heat addition and mean flow

An educational experimental system has been developed for studying tonal sound generation in acoustic resonators. Tones are excited by either heat addition or vortex shedding in the presence of mean flow. The system construction is straightforward and inexpensive. Several test arrangements and experimental data are described in this paper. The experimental setups include a modified Rijke tube, a standing-wave thermoacoustic engine, a baffled tube with mean flow, and an acoustic energy harvester with a piezoelement. Simplified mathematical models for interpreting data are discussed, and references are provided to literature with more advanced analyses. The developed system can assist both graduate and undergraduate students in understanding acoustic instabilities via conducting and analyzing interesting experiments.     

Rijke管自激热声振荡的数值模拟

为了对热声不稳定的发生及控制机理进行研究,对Rijke管内的自激热声振荡现象进行了数值模拟。采用具有低频散低耗散特点的计算气动声学方法,对带有非线性热源项的声波方程进行数值求解,并比较了不同的热源模型及边界条件对非线性效应的影响。结果表明,计算气动声学方法可以成功捕捉到Rijke管内压力的起振过程,而且在速度扰动达到平均流速度的1/3时,振荡会由线性增长转为非线性增长,最终达到有限幅值极限循环。相比热源项,考虑管口辐射耗散的非线性边界条件在振荡幅值和频谱方面对结果的影响都比较小。数值模拟得到的结果与实验符合较好,表明计算气动声学方法适合于热声振荡问题的研究。      

Investigation on nonlinear thermo-acoustic characteristics of Rijke tube

Based on the energy conservation relationship,nonlinear thermo-acoustic effects of Rijke tube including instability range,saturation processes and higher harmonics modes were investigated.With coupling between the external flow and the inner space of a Rijke tube, the acoustic characteristics of self-excited oscillation were simulated.The experimental study was also carried out and the results were compared with those from simulation.The nonlinear factors which distort the acoustic waveform distortion were analyzed.From the results,it is seen that varying size of the nozzle outlet changes the acoustic impedance in the boundary, and leads to reduction of the nonlinear effects.The results show that the modes of self-excited oscillation could be influenced by the position of higher harmonics.In the large amplitude oscillation,the distortion of pressure wave within Rijke tube could be induced by the acoustic losses due to vortices on nozzle.It is found that the waveform distortion could be avoided by the shrinkage of nozzle.     

A study of the transition to instability in a Rijke tube with axial temperature gradient

A horizontal Rijke tube with an electric heat source is a system convenient for studying the fundamental principles of thermoacoustic instabilities both experimentally and theoretically. Given the long history of the device, there is a surprising lack of accurate data defining its behavior. In this work, the main system parameters are varied in a quasi-steady fashion in order to find stability boundaries accurately. The chief purposes of this study are to obtain precise values of the system parameters at the transition to instability with specified uncertainties and to determine how well the experimental results can be explained with existing theory. Measurement errors are reported, and the influence of experimental procedures on the results is discussed. A form of hysteresis effect at stability boundaries has been observed. Mathematical modelling is based on a thermal analysis determining the temperature of the heater and the temperature field in the air inside the tube, which, consequently, affects acoustical mode shapes. Solutions of the linearized wave equation for a non-uniform medium, including losses and a heat source term, determine the stability properties of the eigen modes. Calculated results are compared with experimental data and with results of the modelling based on the common assumption of a constant temperature in the tube. The mathematical model developed here can be applied to designing thermal devices with low Mach number flows, where thermoacoustic issue is a concern.     

黎开管非线热声效应的研究

基于能量守恒原理对Rijke管热声效应展开了理论分析,采用内外流场耦合法数值模拟了Rijke管自激励起振和饱和过程的声场特性,并开展了相应的实验研究.推导了Rijke管起振、饱和及高次谐波产生过程中的能量变化,分析了Rijke管非线性效应包括高次谐波和波形畸变的影响因素,提出了改变管口声阻抗可弱化非线性效应的方法.结果...     

Generation of harmonics in a Rijke tube by using a single heating element

There exist excitation positions in a Rijke tube in which a heating element may be placed to produce a harmonic of the tube. These positions can be predicted from Rayleigh's criterion. A formula is derived to calculate the positions of these points for the inth harmonic. A heating element, placed in both of the two possible positions of excitation, as predicted by this formula, successfully produced the second harmonic of a Rijke tube.     

Transmission and radiation of acoustic oblique incident through tube arrays based on phononic crystals theory

In a utility boiler, the heat exchanger’s structure is similar to a two-dimensional phononic crystal. Based on the phononic crystal theory, this paper studies sound propagation through tube arrays as a function of the incident sound direction and the surroundings temperature. We carried out both the computational and experimental work for particular values of the pitch and diameters in the tube arrays and studied the band-gap diagram and insertion loss spectra for different angles of incidence. The first band gap is found to correspond to Bragg’s Law while the second band gap moves to lower frequencies as the angle increases. Simulations indicate also that the uneven temperature field influences the insertion loss spectrum. Results of experiments and calculations confirm that, for a particular tube array, the most important factors influencing sound propagation are incidence angle and the surrounding temperature. For the acoustic source in tube arrays, the acoustic radiation have relation with the frequency whether in the acoustic bang gap or not. The results should provide a basis for further work: both on sound source localization and low frequency sonic cleaning in large tube arrays.