固体火箭发动机燃烧室三维流动数值计算

采用ｋε双方程湍流模型,以ＳＩＭＰＬＥ 计算程式求解翼柱型装药固体火箭发动机燃烧室内三维非定常不可压流ＮＳ 方程．在建立翼柱型装药简化模型的基础上采用边界标志法来表达燃面推移,采用从二维到三维的初场给定方法结合多重网格法求出了多个时间步的非稳态流场结构．计算结果表明燃烧室内旋涡运动呈现一定的空间与时间分布,周向加质导致燃气通道横断面上轴向速度分布的极不均衡．     

硅基材料烧蚀模型研究

对冲压发动机燃烧室所使用的硅基热防护材料，用以往的单纯因二氧化硅液态层被气动吹除减薄的模型进行烧蚀计算，计算结果和实际偏差很大。我们根据硅基热防护材料的实际特性，在原有的液态层模型的基础上，考虑了夹杂碳化层对熔融态硅基的补强作用，提出了既有液态层吹除也有化学反应烧蚀的新模型，即考虑了热解、熔融和碳化、气动吹除结合化学反应烧蚀的多因素过程。并根据硅基热防护材料的烧蚀特点，根据发动机模型的试验结果，初步总结出了液态层粘附力的经验公式。从物理概念上分析可以看出该模型基本符合实际情况；从多种工况计算结果可看出，新模型和经验公式是比较合理的。     

塞式喷管单元发动机实验与数值模拟研究

简要介绍固体推进剂模拟塞式喷管单元发动机实验系统，给出了实验塞式喷管型面设计方法和特征线法在塞式喷管流场计算中的应用，癖结了实验研究结果，并同数值模拟计算结果进行了比较，主要结果包括燃烧室压力，底部气锥流量，内膨胀比，侧喷管倾角，底部压缩角等对塞式喷管性能的影响，并得出了塞式喷管单元发动机推力方向与其轴线方向夹角的高度特性。     

动叶顶部间隙结构对涡轮性能影响的数值分析

富氧燃气中工作的涡轮动叶顶部间隙较大,导致泄漏损失很大。通过对四种不同动叶顶部结构的涡轮级进行流场数值模拟,比较了其对涡轮性能、流场的影响。结果表明,动叶顶部围带与壳体迷宫结构的泄漏量最小,因而效率损失最小。     

长空发动机转速状态的调整规律

“长空发动机的控制是通过设计几个转速状态来实现的。但转速状态的调整一直比较困难。本文从理论上对此作了深入的分析,提出了简便的调整方法,给出了由实验得到的调整数据。     

Spectral analysis and self-adjusting mechanism for oscillation phenomenon in hydrogen-oxygen continuously rotating detonation engine

The continuously rotating detonation engine(CRDE)is a new concept of engines for aircraft and spacecraft.Quasi-stable continuously rotating detonation(CRD)can be observed in an annular combustion chamber,but the sustaining,stabilizing and adjusting mechanisms are not yet clear.To learn more deeply into the CRDE,experimental studies have been carried out to investigate hydrogen-oxygen CRDE.Pressure histories are obtained during each shot,which show that stable CRD waves are generated in the combustor,when feeding pressures are higher than 0.5 MPa for fuel and oxidizer,respectively.Each shot can keep running as long as fresh gas feeding maintains.Close-up of the pressure history shows the repeatability of pressure peaks and indicates the detonation velocity in hydrogen–oxygen CRD,which proves the success of forming a stable CRD in the annular chamber.Spectrum of the pressure history matches the close-up analysis and confirms the CRD.It also shows multi-wave phenomenon and affirms the fact that in this case a single detonation wave is rotating in the annulus.Moreover,oscillation phenomenon is found in pressure peaks and a self-adjusting mechanism is proposed to explain the phenomenon.     

An IPC-based Prolog design pattern for integrating backward chaining inference into applications or embedded systems

Prolog is one of the most important candidates to build expert systems and AI-related programs and has potential applications in embedded systems. However, Prolog is not suitable to develop many kinds of components, such as data acquisition and task scheduling, which are also crucial. To make the best use of the advantages and bypass the disadvantages, it is attractive to integrate Prolog with programs developed by other languages. In this paper, an IPC-based method is used to integrate backward chaining inference implemented by Prolog into applications or embedded systems. A Prolog design pattern is derived from the method for reuse, whose principle and definition are provided in detail. Additionally, the design pattern is applied to a target system, which is free software, to verify its feasibility. The detailed implementation of the application is given to clarify the design pattern. The design pattern can be further applied to wide range applications and embedded systems and the method described in this paper can also be adopted for other logic programming languages.     

Efficiency optimized fuel supply strategy of aircraft engine based on air-fuel ratio control

Accurate fuel injection control of aircraft engine can optimize the energy efficiency of UAV power system while meeting the propeller speed requirement. Traditional injection control method such as open-loop calibration causes instability of fuel supply which brings the risk of power loss of UAV. Considering that the closed-loop control of AFR can ensure a stable fuel feeding, this paper proposes an AFR control based fuel supply strategy in order to improve the efficiency of fuel-powered UAV while obtaining the required engine speed. According to the optimum fuel injection results, we implement fuzzy-PID method to control the set AFR in different situations. Through simulation and experiment studies, the results indicate that, to begin with, the calibrated mathematical model of the aircraft engine is effective. Next, this fuel supply strategy based on AFR control can normally realize the engine speed regulation, and the applied control algorithm can eliminate the overshoot of AFR throughout all the working progress. What is more,the fuel supply strategy can averagely shorten the response time of the engine speed by about two seconds. In addition, compared with the open-loop calibration, in this work the power efficiency is improved by 9% to 33%. Last but not the least, the endurance can be improved by 30 min with a normal engine speed. This paper can be a reference for the optimization of UAV aircraft engine.     

Inverted decoupling and LMI-based controller design for a turboprop engine with actuator dynamics

The main objective of the turboprop engine control system is to ensure propeller absorbed power at a constant propeller speed by controlling fuel flow and blade angle. Since each input variable affects the selected output variables, there exist strong interactions between different control loops of a Two-Spool TurboProp Engine (TSTPE). Inverted decoupling is used to decouple the interactions and decompose the TSTPE into two independent single-input single-output systems. The multi-variable PI controller and two single-variable PI controllers are designed for the TSTPE with actuator dynamics based on Linear Matrix Inequality (LMI), respectively, which is derived from static output feedback and pole placement condition. The step responses show that due to the difference in the response times of the selected output variables, it is difficult to design an appropriate multi-variable PI controller. The designed single-variable PI controllers are tested on the TSTPE integrated model to illustrate the effectiveness of the proposed method, that is, the interactions are first decoupled and then the controllers are designed, and the resulting simulated responses show that compared with the controller designed without actuator dynamics, the gas-generator shaft speed and power turbine shaft speed can better track their respective commands under the action of the controller designed with actuator dynamics.     

航空发动机H_∞控制器设计方法

本文提出了一种结构摄动系统鲁棒控制器综合方法。采用该方法可以同时考虑闭环系统的频域设计要求及对结构摄动的鲁棒稳定性。该方法被用于某型双转子涡喷航空发动机稳态控制器的设计，并取得了良好效果。