燃气轮机涡轮叶顶间隙气热技术研究进展

涡轮叶顶间隙泄漏流动对其流道内气动损失、传热状况甚至总体效率都有较为明显的影响,是降低涡轮气热性能的关键因素之一。长期以来,叶顶间隙区域的流动传热机理及其气热控制一直是燃气轮机领域研究的一个热点和难点问题。鉴于此,从叶顶间隙泄漏流动机理及影响因素、间隙泄漏控制方法、叶顶传热冷却机理、影响因素与控制、叶顶间隙气热优化以及过渡态叶顶间隙变化规律及建模与控制等方面对国内外近十年来涡轮叶顶间隙气热技术方面的研究进展进行综述,并简要总结了叶顶间隙泄漏流的常用研究方法,包括流动传热试验与数值计算方法等。最后,对涡轮叶顶间隙气热技术的未来研究重点和发展趋势进行了展望。     

铁基金刚石节块的热处理及其耐磨性能研究

首次提出了在烧结型金刚石工具的制造中引入热处理的新工艺，并系统地研究了淬火温度、淬火时间及回火温度等热处理工艺参数对热压烧结型铁基金刚石圆盘锯节块及其胎体材料机械性能的影响，同时对经热处理的铁基金刚石圆盘锯节块在石材旺苍红上进行磨损试验研究。试验结果表明，热压烧结型铁基金刚石圆盘锯节块胎体热处理的最佳工艺参数为：淬火温度为７６０～７９０℃、淬火时间为３．５ｍｉｎ、回火温度为２４５～３１５℃；经热处理后铁基金刚石圆盘锯胎体及节块的强度、硬度等机械性能有显著的提高，热处理也能明显改善铁基金刚石圆盘锯节块的耐磨性能。这说明将热处理工艺用于烧结型金刚石工具的制造中是切实可行的。     

考虑轨道摄动的外热流计算分析

为改进传统外热流算法未考虑外热流经多次反射后的吸收和国外商业软件未考虑轨道摄动及太阳矢量变化对外热流的影响等不足,重新定义了外热流角系数和外热流辐射传递因子,综合SGP4轨道模型和Gebhart方法,给出了考虑摄动等因素的辐射传递因子和轨道外热流计算模型,以及相应的计算流程。通过仿真分析论证了考虑多次反射及摄动等因素的重要性。     

航空发动机进气支板电热防冰试验

为了研究电加热防冰的效果,开展了小型航空发动机进气支板的电加热防冰试验。结合该型号发动机进气支板的结构特点,设计了3种电热防冰加热布置方式,分别在支板沿轴向的不同位置采用1~3个电加热棒作为防冰热源。通过模拟不同的发动机进气结冰环境参数和电加热功率,在冰风洞中对3种电加热方式进行了防冰试验研究。通过布置在支板外表面的温度测点记录了防冰过程中支板表面的瞬态温度变化,分析了支板防冰过程中表面温度的变化特点。防冰试验研究了热源总功率、热源布置方式、液态水含量以及来流温度对支板防冰性能的影响。试验结果表明,合理的电加热方式可以取得较好的防冰效果,同时避免支板后部的溢流水结冰。     

Experimental investigation and correlation development of jet impingement heat transfer with two rows of aligned jet holes on an internal surface of a wing leading edge

Extensive experimental studies on the heat transfer characteristics of two rows of aligned jet holes impinging on a concave surface in a wing leading edge were conducted, where50000 Rej 90000, 1.74 H/d 27.5, 66° a 90°, and 13.2 r/d 42.03. The finding was that the heat transfer performance at the jet-impingement stagnation point with two rows of aligned jet holes was the same as that with a single row of jet holes or the middle row of three-row configurations when the circumferential angle of the two jet holes was larger than 30°. The attenuation coefficient distribution of the jet impingement heat transfer in the chordwise direction was so complicated that two zones were divided for a better analysis. It indicated that: the attenuation coefficient curve in the jet impingement zone exhibited an approximate upside-down bell shape with double peaks and a single valley; the attenuation coefficient curve in the non-jet impingement zone was like a half-bell shape, which was similar to that with three rows of aligned jet holes; the factors,including Rej, H/d and r/d, affected the attenuation coefficient value at the valley significantly.When r/d was increased from 30.75 to 42.03, the attenuation rates of attenuation coefficient increased only by 1.8%. Consequently, experimental data-based correlation equations of the Nusselt number for the heat transfer at the jet-impingement stagnation point and the distributionof the attenuation coefficient in the chordwise direction were acquired, which play an important role in designing the wing leading edge anti-icing system with two rows of aligned jet holes.     

Aerothermodynamic and stability analyses of a deployable re-entry capsule

Recent research projects, in the field of atmospheric re-entry technology, are focused on the design of deployable, umbrella-like Thermal Protection Systems (TPSs). These TPSs are made of flexible high temperature resistant fabrics, folded at launch and deployed in space for de-orbit and re-entry operations. In the present paper two possible sphere–cone configurations for the TPS have been investigated from an aerodynamic point of view. The analyzed configurations are characterized by the same reentry mass and maximum diameter, but have different half-cone angles (45° and 60°). The analyses involve both the evaluation of thermal and aerodynamic loads and the assessment of the capsule longitudinal stability. The aerothermodynamic analysis has been performed for the completely deployed heat shield in transitional and continuum regimes, while the longitudinal stability has been analyzed in free molecular, transitional and continuum regimes, also taking into consideration the heat shield deployment sequence at high altitudes.     

改进的电热除冰系统的仿真方法

建立了电热除冰系统矩形微段的二维简化物理模型，采用焓法模型建立相变导热问题的微分控制方程，用控制容积法对该模型的控制方程及其边界、初始条件进行离散，使用块修正技术对原有的离散方程组的求解方法进行了改进，得到各个时刻的温度分布及冰的融解情况。计算结果与国外文献结果吻合，验证了改进的算法和程序的正确性。并计算分析了时间步长的选择、网格的划分对计算结果的影响。     

烧结双多孔介质中沸腾换热的实验研究

对由铜粉烧结而成的三种双多孔介质结构进行了沸腾换热的实验。为了便于比较，同时对两种单多孔介质进行了沸腾换热实验。结果发现：当双多孔介质的微孔径和单多孔介质的孔径相同时，双多孔介质的换热系数和临界热流密度比单多孔介质高得多；对于同样微孔径的双多孔介质，存在最佳的粗孔径，其换热系数和临界热流密度最大；当逆静水压头减小的时候，换热系数和临界热流密度增加。     

国外新型热作模具钢及其热处理工艺

主要叙述了H13、QRO80M、QRO90SUPREME等新型热作模具钢的性能、使用特点及其热处理工艺技术方法。     

液体火箭发动机涡轮泵用机械密封温度场及热载变形研究

基于ANSYS数值计算软件,建立了液体火箭发动机涡轮泵用机械密封的二维稳态传热模型,依靠经验公式确定了模型的对流换热系数。计算了密封环的温度场和热载变形,分析了密封端面比压、回流流量以及不同材质对密封温度场的影响规律。结果表明:密封端面最高温度发生在靠近密封环内径处,且密封端面比压越大密封环温度梯度越大;密封环热载变形呈收敛间隙,最大变形发生在动环端面的外径处,其值约为2.2μm;密封环端面最高温度随回流流量增加而减小,当回流流量从0.1~0.6 kg/s变化时,密封环端面最高温度可降低18%(从100℃降至82℃);当回流流量增大到0.3 kg/s时,继续提高对密封环端面温升的控制不再显著;采用高导热系数的摩擦副材料能够显著降低端面温升和温度梯度,提高密封工作可靠性。