Simulation and Experiment for Oxygen-enriched Combustion Engine Using Liquid Oxygen to Solidify CO2

For capturing and recycling of CO2 in the internal combustion engine, Rankle cycle engine can reduce the exhaust pollutants effectively under the condition of ensuring the engine thermal efficiency by using the techniques of spraying water in the cylinder and optimizing the ignition advance angle. However, due to the water spray nozzle need to be installed on the cylinder, which increases the cylinder head design difficulty and makes the combustion conditions become more complicated. In this paper, a new method is presented to carry out the closing inlet and exhaust system for internal combustion engines. The proposed new method uses liquid oxygen to solidify part of cooled CO2 from exhaust system into dry ice and the liquid oxygen turns into gas oxygen which is sent to inlet system. The other part of CO2 is sent to inlet system and mixed with oxygen, which can reduce the oxygen-enriched combustion detonation tendency and make combustion stable. Computing grid of the IP52FMI single-cylinder four-stroke gasoline-engine is established according to the actual shape of the combustion chamber using KIVA-3V program. The effects of exhaust gas recirculation （EGR） rate are analyzed on the temperatures, the pressures and the instantaneous heat release rates when the EGR rate is more than 8%. The possibility of enclosing intake and exhaust system for engine is verified. The carbon dioxide trapping device is designed and the IP52FMI engine is transformed and the CO2 capture experiment is carried out. The experimental results show that when the EGR rate is 36% for the optimum EGR rate. When the liquid oxygen of 35.80-437.40 g is imported into the device and last 1-20 min, respectively, 21.50-701.30 g dry ice is obtained. This research proposes a new design method which can capture CO2 for vehicular internal combustion engine.

Analysis of Magnetic Positioning for Liquid Oxygen Under Microgravity Condition

Due to the paramagnetic property of liquid oxygen,the Kelvin force can be induced in liquid oxygen under non-uniform magnetic field.Based on the volume of fluid(VOF)model,the positioning effect of the force in liquid oxygen tanks is analyzed under various Bond numbers(Bo)and magnetic Bond numbers(Bom).The results show that the magnetic field has the effect of repositioning the liquid oxygen in the tank when the gravity field is not enough or absent.Additionally,the gas-liquid interface has a periodic fluctuation during the process due to the inhomogeneous Kelvin force distribution,and more effective suppression of fluctuation can be achieved under the condition of a larger Bom.The new method of controlling gas-liquid interface of liquid oxygen tank under micro gravity condition is hoped to be developed in the future.

Study on fluid-structure interaction in liquid oxygen feeding pipe systems using finite volume method

The fluid-structure interaction may occur in space launch vehicles,which would lead to bad performance of vehicles,damage equipments on vehicles,or even affect astronauts＇ health.In this paper,analysis on dynamic behavior of liquid oxygen （LOX） feeding pipe system in a large scale launch vehicle is performed,with the effect of fluid-structure interaction （FSI） taken into consideration.The pipe system is simplified as a planar FSI model with Poisson coupling and junction coupling.Numerical tests on pipes between the tank and the pump are solved by the finite volume method.Results show that restrictions weaken the interaction between axial and lateral vibrations.The reasonable results regarding frequencies and modes indicate that the FSI affects substantially the dynamic analysis,and thus highlight the usefulness of the proposed model.This study would provide a reference to the pipe test,as well as facilitate further studies on oscillation suppression.

Gas film/regenerative composite cooling characteristics of the liquid oxygen/liquid methane (LOX/LCH4) rocket engine

The thermal protection of rocket engines is a crucial aspect of rocket engine design.In this paper,the gas film/regenerative composite cooling of the liquid oxygen/liquid methane(LOX/LCH4)rocket engine thrust chamber was investigated.A gas film/regenerative composite cooling model was developed based on the Grisson gas film cooling efficiency formula and the one-dimensional regenerative cooling model.The accuracy of the model was validated through experiments conducted on a 6 kg/s level gas film/regenerative composite cooling thrust chamber.Additionally,key parameters related to heat transfer performance were calculated.The results demonstrate that the model is sufficiently accurate to be used as a preliminary design tool.The temperature rise error of the coolant,when compared with the experimental results,was found to be less than 10%.Although the pressure drop error is relatively large,the calculated results still provide valuable guidance for heat transfer analysis.In addition,the performance of composite cooling is observed to be superior to regenerative cooling.Increasing the gas film flow rate results in higher cooling efficiency and a lower gas-side wall temperature.Furthermore,the position at which the gas film is introduced greatly impacts the cooling performance.The optimal introduction position for the gas film is determined when the film is introduced from a single row of holes.This optimal introduction position results in a more uniform wall temperature distribution and reduces the peak temperature.Lastly,it is observed that a double row of holes,when compared to a single row of holes,enhances the cooling effect in the superposition area of the gas film and further lowers the gas-side wall temperature.These results provide a basis for the design of gas film/regenerative composite cooling systems.

INTERACTION OF PLASMA—LIQUID IN AN OXYGEN GLOW DISCHARGE Ⅲ.OXIDATION DESULFURIZATION OF ETHYL—THIOETHER

A few factors affecting plasma oxidation desulfurization of ethyl- thioether were investigated.Under the typical conditions,the conversion and degree of desulfurization of ethyl-thioether can be achieved up to 88% and 79% respectively.

诱导轮对高速液氧泵空化流场影响研究

高抗空化诱导轮可以改善液氧泵的空化特性,提高大推力火箭的可靠性。基于计算流体力学方法,建立了高速液氧泵的流动仿真模型,通过三组试验工况验证了模型准确性,研究了诱导轮叶片数对液氧泵性能和空化特性的影响。结果表明:使用诱导轮可以减小离心轮空化面积,代偿离心轮的汽蚀,提高液氧泵扬程;在入口流量和出口压力不变的条件下,增加诱导轮叶片数,液氧泵的效率增加,扬程降低,离心轮空化面积增加,诱导轮代偿离心轮汽蚀能力削弱。综合考虑液氧泵性能参数和空化特性,三叶片诱导轮能够满足大推力液体火箭的高可靠性要求。

液氧煤油掺混及燃爆特性试验研究

为研究液氧煤油掺混及燃爆特性,建立部分受限空间试验系统以模拟发射场应用场景,开展液氧煤油掺混及燃爆特性试验。试验结果表明,液氧、煤油同时泄出并掺混时,煤油、氧气浓度均存在一个先上升后下降的过程;当煤油温度为65℃、点火激励为5.9J时,即使是发生液氧泄漏,液面上方布置的测点处仍未达到燃爆条件;煤油温度提升至80℃时,液氧持续泄出仅约20s时成功起爆,点火时刻煤油蒸气浓度1.31%,氧气浓度40.05%,氮气浓度58.64%,煤油/氧气浓度比值为0.033。

液氧甲烷重复使用运载器关键技术发展研究

基于液氧甲烷发动机的重复使用运载器在重复使用和使用维护方面具有优良的性能,成本更低。世界各国正在加速开展相关研究及工程研制,典型代表包括火神运载火箭、朱雀二号运载火箭等。对基于液氧甲烷发动机的重复使用运载器的技术特点、面临的技术挑战进行分析,并基于此提出后续重点研究内容,包括重复使用总体设计与评估技术、上升再入返回着陆一体化制导导航与控制技术、大尺寸轻质结构与制造技术、重复使用液氧甲烷发动机技术、健康管理预测与重复使用运行维护技术、重复使用热防护技术等,为后续开展液氧甲烷重复使用运载器工程研制奠定基础。

液氧液氢发动机领域知识图谱构建与应用

液氧液氢发动机作为航天领域的关键分系统,为有效开展其研制过程的智能化转型工作,针对液氧液氢发动机领域构建知识图谱,在储备领域知识的同时,提高科研生产人才的培养能力。针对液氧液氢发动机领域特点,对领域语料标注、领域知识识别、实体关系识别3个方面进行了研究,在此基础上进行了领域知识图谱的构建,并从领域知识搜索、知识推荐、探索式分析3个角度梳理了其业务应用模式。形成了液氧液氢发动机领域知识体系,并提出构建方法和应用模式。研究结果为航天领域智能化转型提供了参考。

面向池塘圈养模式的气液混合泵的参数优化及增氧试验

为探究气液混合泵能否满足在高密度养殖条件下养殖对象对水体溶氧的需求,基于气液(氧气-水)混合泵搭建溶氧试验平台,在不同水温、不同出水压力和不同气水体积比的条件下,测试气液混合泵溶氧性能,并在池塘圈养桶(直径4 m,高2 m,养殖水体体积20 m^(3))内进行增氧试验。溶氧性能测试结果显示:当出水压力为0.25 MPa、气水体积比为0.01~0.05时,在不同水温(5.6、13.5、30.3)条件下出水溶解氧与水温成反比,溶解氧在47.93~20.60 mg/L变化;氧气吸收效率与气水体积比呈反比,氧气吸收效率在91%~33.7%变化;动力效率与气水体积比成正比,动力效率在22.32~55.12 kg/(kW·h)变化。基于圈养桶的增氧试验结果显示,在有鱼耗氧的条件下(黄颡鱼,单个桶内养殖密度为13.19~16.49 kg/m^(3)),使用功率3 kW的气液混合泵为4个圈养桶增氧时,每个桶内水体溶解氧在光照时间内可达11 mg/L,夜间稳定保持在8 mg/L以上。试验结果表明气液混合泵可应用于高密度的水产养殖,并能有效应对夏季高温供氧难题。

液氧煤油火箭海上发射基本方案及关键技术分析

海上发射火箭在提升火箭运载能力、降低残骸坠落风险等方面具有极大优势。我国已成功实施多型固体火箭海上发射任务,相比固体火箭,液氧煤油火箭具有更高的比冲和环保性。根据液氧煤油火箭陆基发射的特点规律和固体火箭海上发射任务流程及实施方案,研究了海射系统港口基地、海上发射船、运载火箭、保障船等运行的基本方案,提出海上发射任务实施流程,分析了牵制释放、连接器零秒脱落和自动对接、无人值守推进剂加注技术在海上发射火箭中的重要意义,以及需要解决的关键技术难题。

液氧甲烷变推力发动机螺旋槽再生冷却传热特性研究

为探究宽工况范围下螺旋槽再生冷却的传热特性,基于微小通道内低温工质的相变传热模型,采用一维传热计算方法,对5 kN级液氧甲烷变推力发动机开展了螺旋槽再生冷却传热特性研究。结果表明:本文所采用的传热计算模型可用于传热预估,与试验结果相比,冷却剂温升误差为4.3%,压降误差为1.1%,喉部处外壁温误差为-11%,在工程计算可接受范围内;相比于直槽,螺旋槽再生冷却能有效降低燃气侧壁温,同时,在宽范围变推力条件下,实际功率水平越低,冷却剂温升、压降越小,喉部燃气侧壁温越低,但“传热恶化区”内的壁温最大值反而越高,当发动机推力由额定工况的75%调整至20%时,燃气侧壁温的最大值由1 351 K增大至1 399 K;综合考虑壁面温度及冷却剂的压力损失,本文对冷却通道开展优化设计,对比四种冷却通道方案的传热性能,其中,方案4为最优方案,20%额定功率水平工况时,冷却剂温升为491 K,压降为0.34 MPa,燃气侧壁温最大值也仅为1 297 K,较初始设计方案降低了102 K,远低于材料的极限温度。

液氧深度过冷大流量加注关键技术研究

为了提高火箭运载系数和工作稳定性,有必要对液氧(LO_(2))深度过冷大流量加注进行研究。重点分析了国内外液氧深度过冷大流量加注的工程应用方案及关键设计参数,总结给出了液氧深度过冷大流量加注技术难点,提出了泵抽真空过冷与高压氮气引射抽真空过冷两种液氧深度过冷大流量加注设计方案。通过对液氧深度过冷大流量加注关键技术研究,为我国深度过冷液氧在低温火箭上大规模应用与地面加注系统的能力提升提供了技术参考。

含固氧颗粒的液氢传输管路中静电积聚仿真研究

为探究含固态氧颗粒的液氢管道传输中静电积聚规律,基于COMSOL Multiphysics软件,开展了液氢-固氧体系荷电规律仿真预示。采用拉格朗日颗粒轨道法与计算流体动力学分别描述连续液氢流与离散固氧颗粒的运动,采用Materials Studio软件计算获得固氧电学性质,并通过电容器法描述固氧颗粒碰撞起电规律,实现固液两相流与静电场的耦合求解。仿真结果发现,当液氢流速为10 m·s^(-1),固氧颗粒粒径为1000μm时,固氧颗粒比电荷达10μC·kg^(-1),颗粒饱和电量约为84 pC,两相流电荷密度为2.84×10^(-4)C·m^(-3),较纯液氢流静电大8个量级。随着颗粒-壁面碰撞次数增多,颗粒荷电量趋于饱和。管流参数对荷电规律影响显著,颗粒比电荷随颗粒质量流量增加略有降低,随管长增加和管径减小而增大,随液氢流速增加呈现先减小后增大的趋势,即存在极小值。颗粒物性也会对荷电量产生影响,颗粒比电荷随粒径增大存在极小值和极大值,颗粒杨氏模量、电阻率、密度等也对荷电规律具有一定影响。研究工作可为液氢传输系统设计与安全防护提供理论支撑。

液氧中水分与二氧化碳冰晶杂质特性可视化实验及分析

针对低温推进剂中高沸点杂质过冷结晶可能堵塞滤网影响输送的问题,本文设计并搭建了能够显微观察液氧中冰晶与二氧化碳杂质状态的实验系统。可视化研究了不同温度液氧中微量水、二氧化碳杂质的生成及性状变化特征。发现当水分、二氧化碳共存于液氧时,部分水分率先形成细密冰晶,并与二氧化碳一同生成松散絮状结构;当该结构内的水冰晶达到饱和态后,其形状基本不再改变,而残余的水分逐渐形成游离态冰晶;絮状结构在90K降温到65 K的过程中发生崩解,杂质的平均尺寸减小了50%以上,有利于含杂质液氧通过滤网。研究所获得的微量杂质冰晶性状变化规律,可为实际应用中火箭充注管路滤网设计和流动阻力计算提供实验参考依据。

液氧液甲烷同温共底贮存瞬态热力特性仿真研究

针对大面积冷屏保护下的液氧/液甲烷同温共底贮箱,建立了耦合真空多层绝热与主动制冷系统的瞬态传热模型,研究了液氧/液甲烷共底自增压与零蒸发贮存过程中贮箱外部绝热结构与内部气液相的热力参数变化规律,讨论了共底夹层采用不具有绝热能力的材料对液氧/液甲烷共底零蒸发贮存特性的影响。研究结果表明,在适当的冷量输入条件下,大面积冷屏方案可以实现外界漏热的有效阻挡;采用铝合金共底夹层有利于稳定液氧和液甲烷的共底贮存状态,使液氧/液甲烷在20 h内快速达到热平衡;在零蒸发贮存周期内,液氧/液甲烷共底贮存温度波动小于0.2 K,压力波动小于2.46 kPa且具有抗热扰动的能力。

微重力下火箭推进系统液氧贮箱内气泡脱离半径研究

研究微重力下液氧贮箱内气泡脱离半径是运载火箭推进系统推进剂在轨沸腾与换热计算的基础.与常重力和低重力环境不同,微重力下Marangoni效应变得突出.为了求解气泡脱离半径,构建包含浮力、惯性力、压差力、表面张力、黏性阻力和Marangoni力的气泡动力学模型.针对现有Marangoni力计算公式适用范围狭窄的问题,依托数值仿真方法,拟合得到了更精确的修正因子计算公式,进而扩充了Marangoni力计算模型的适用范围.使用运载火箭液氧贮箱常规工作压力0.3 MPa下的饱和液氧物性参数,计算得到气泡所受合力随半径的变化关系以及气泡脱离半径随重力的变化关系.结果表明,气泡的脱离行为可以由微重力区、过渡区和低重力区三个区域来划分.微重力区内可以形成厘米级甚至米级的大气泡,而低重力区内只能形成0.1 mm级的小气泡.相比之前的模型,本文模型可以同时适用于三个区,更全面地揭示了微重力下液氧贮箱内的气泡脱离特性,可以为液氧贮箱换热特性分析提供理论支撑.

调节阀低温空化流动特性的数值仿真

采用数值计算的方法针对某型液体火箭发动机中液氧调节阀的流场分布和空化流动特性进行了研究。数值计算获得的阀门流通面积与液流实验数据基本吻合,验证了数值模型的准确性。分析了球阀内部流道压力、温度、涡和空穴结构的分布特性及不同工况下的演化规律。研究结果表明:液氧流经球阀,压力变化分为缓慢下降、急剧下降、急剧回升、缓慢下降和缓慢回升这5个阶段。在阀芯流道内部观察到了显著的Q等值面结构。相同压差时,水的空化数大于液氧。空穴结构主要分布在阀芯入口,随着空化数的降低,逐渐向流道内部发展。对于常温水,发生空化的临界空化数为1.38左右。空穴结构的发展受空化数和热力学效应的耦合影响。液氧温度从95 K上升到100 K时,空化数减小,名义温降增加,此时热力学效应影响起主导作用,空穴的发展受到抑制。

不同设计参数对液氧甲烷发动机喷管效率的影响

为了更好更快地计算喷管性能,采用特征线法加附面层修正的方式开发了一种二维喷管化学动力流场计算程序,针对某液氧甲烷发动机计算了不同设计参数对应的喷管流场,研究了不同设计参数对喷管效率的影响,设计参数包括推力、室压、喷管面积比和喷管出口角等。计算喷管效率时考虑了几何损失、附面层损失、化学动力损失。结果表明使用程序计算能够准确快速获得工程上重视的设计指标,大大提高了仿真效率,可用于喷管型面优化。

地塞米松预充对小儿心脏手术肺氧合功能的影响

目的观察体外循环体外循环(CPB)预充液中应用地塞米松对小儿心脏手术肺氧合功能的影响,为临床实践提供相应的依据。方法选取2023年2月至2024年1月贵阳市妇幼保健院心脏中心收治的行室间隔缺损修补术和(或)房间隔缺损修补术的先天性心脏病(CHD)患儿54例作为研究对象,随机将其分为对照组和地塞米松组,每组27例。对照组未给予地塞米松治疗,地塞米松组预充液中加入5 mg/kg地塞米松,分别于麻醉诱导后CPB前(T_(0))、CPB 15 min(T_(1))、主动脉开放前5 min(T_(2))、CPB结束时(T_(3))、入重症监护室(ICU)后2 h(T_(4))取血样进行动脉血气分析,计算呼吸指数(RI)、氧合指数(OI)、动脉肺泡氧分压比值(PaO_(2)/PAO_(2),a/A),记录术前一般状况及围手术期参数。结果对照组RI指标在T_(2)时点为2.52±2.57,显著高于地塞米松组(1.39±1.42),差异有统计学意义(P<0.05);2组患者OI、a/A指标比较,差异均无统计学意义(P>0.05)。术后气管拔管率及ICU机械通气时间比较,差异均无统计学意义(P>0.05)。结论CPB预充液中给予地塞米松可在一定程度上在一定时间段内改善CPB后肺氧合功能。