Investigations on High-Speed Flash Boiling Atomization of Fuel Based on Numerical Simulations

Flash boiling atomization(FBA)is a promising approach for enhancing spray atomization,which can generate a fine and more evenly distributed spray by increasing the fuel injection temperature or reducing the ambient pressure.However,when the outlet speed of the nozzle exceeds 400 m/s,investigating high-speed flash boiling atomization(HFBA)becomes quite challenging.This difficulty arises fromthe involvement ofmany complex physical processes and the requirement for a very fine mesh in numerical simulations.In this study,an HFBA model for gasoline direct injection(GDI)is established.This model incorporates primary and secondary atomization,as well as vaporization and boilingmodels,to describe the development process of the flash boiling spray.Compared to lowspeed FBA,these physical processes significantly impact HFBA.In this model,the Eulerian description is utilized for modeling the gas,and the Lagrangian description is applied to model the droplets,which effectively captures the movement of the droplets and avoids excessive mesh in the Eulerian coordinates.Under various conditions,numerical solutions of the Sauter mean diameter(SMD)for GDI show good agreement with experimental data,validating the proposed model’s performance.Simulations based on this HFBA model investigate the influences of fuel injection temperature and ambient pressure on the atomization process.Numerical analyses of the velocity field,temperature field,vapor mass fraction distribution,particle size distribution,and spray penetration length under different superheat degrees reveal that high injection temperature or low ambient pressure significantly affects the formation of small and dispersed droplet distribution.This effect is conducive to the refinement of spray particles and enhances atomization.

Effect of Gd on neutron absorption properties and electrochemical corrosion behavior of Zr-Gd alloy in boiling concentrated HNO3

A Zr-Gd alloy with neutron poisoning properties and resistance to boiling concentrated HNO3 corrosion was developed based on a corrosion-resistant Zr-702 alloy to meet the demand for neutron shielding in the closed-loop treatment of spent fuel and the nuclear chemical industry.In this study,1 wt.%,3 wt.%,5 wt.%,7 wt.%,and 9 wt.%Zr-Gd alloys were designed and fabricated with Zr-702 as the control element.The electrochemical behavior of the Zr-Gd alloys in boiling concentrated HNO3 was investigated,and the neutron shielding effect on plate thickness and Gd content was simulated.The experimental results demonstrate that the corrosion resistance of the alloy decreased slightly before~7-9 wt.%with increasing Gd content;this is the inflection point of its corrosion resistance.The alloy uniformly dissolved the Gd content that could not be dissolved in the Zr lattice,resulting in numerous micropores on the passivation coating,which deteriorated and accelerated the corrosion rate.The MCNP simulation demonstrated that when the Gd content was increased to 5 wt.%,a 2-mm-thick plate can shield 99.9%neutrons;an alloy with a Gd content≥7 wt.%required only a 1-mm-thick plate,thereby showing that the addition of Gd provides an excellent neutron poisoning effect.Thus,the corrosion resistance and neutron shielding performance of the Zr-Gd alloy can meet the harsh service requirements of the nuclear industry.

Simulation of single bubble dynamic process in pool boiling process under microgravity based on phase field method

We use the phase field method to track the gas-liquid interface based on the gas-liquid two-phase flow in the pool boiling process,and study the bubble nucleation,growth,deformation,departure and other dynamic behaviors on the heating surface under microgravity.By simulating the correlation between liquid undercooling and bubble dynamics,we find that the bubble growth time increases with the increase of liquid undercooling,but the effect of liquid undercooling on bubble height is not significant.Meanwhile,the gas-liquid-solid three-phase contact angle and the gravity level will also have an effect on the bubble growth time and bubble height.With the increase of the contact angle,the bubble growth time and bubble height when the bubble departs also increase.While the effect of gravity level is on the contrary,the smaller the gravity level is,the larger the bubble height and bubble growth time when the bubble separates.

Comparisons of Structured Surface Floors for Pool Boiling Enhancement at Low Heat Fluxes: Hands-On Learning Setup for Heat Transfer Classroom

Various enhanced surfaces have been proposed over the years to improve boiling heat transfer. This paper introduces an experimental setup designed for boiling demonstration in the graduate-level Heat Transfer course. The pool boiling performance of water under atmospheric pressure of 1.025 bar is investigated by using several structured surfaces at heat fluxes of 28 and 35 kW/m2. Surfaces with holes, rectangular grooves, and mushroom fins are manufactured by an NC-controlled vertical milling machine. The heat flux versus excess temperature graph is plotted by using thermocouple measurements of water and base temperatures of the boiling vessel. The separation, rise, and growth of individual vapor bubbles from the surface during boiling were recorded with a digital camera. The results for the plain surface are compared to the Rohsenow correlation. The enhancement of heat transfer coefficient (h) ranged between 15% - 44.5% for all structured surfaces. The highest heat transfer coefficient enhancement is observed between 41% - 56.5% for holed surface-3 (405 holes) compared to the plain surface. The excess temperature dropped around 29% - 34% for holed surface-3 (405 holes) compared to the plain surface. The heat transfer coefficient increases as the spacing between channels or holes decreases. While the bubbles on holed and mushroomed surfaces were spherical, the bubbles on the flat and grooved surfaces were observed as formless. The suggested economical test design could be appropriate to keep students focused and participating in the classroom.

Experimental and Numerical Analysis of the Influence ofMicrochannel Size and Structure on Boiling Heat Transfer

Computational fluid dynamics was used and a numerical simulation analysis of boiling heat transfer in microchannels with three depths and three cross-sectional profiles was conducted.The heat transfer coefficient and bubble generation process of three microchannel structures with a width of 80μm and a depth of 40,60,and 80μm were compared during the boiling process,and the factors influencing bubble generation were studied.A visual test bench was built,and test substrates of different sizes were prepared using a micro-nano laser.During the test,the behavior characteristics of the bubbles on the boiling surface and the temperature change of the heated wall were collected with a high-speed camera and a temperature sensor.It was found that the microchannel with a depth of 80μm had the largest heat transfer coefficient and shortest bubble growth period,the rectangular channel had a larger peak heat transfer coefficient and a lower frequency of bubble occurrence,while the V-shaped channel had the shortest growth period,i.e.,the highest frequency of bubble occurrence,but its heat transfer coefficient was smaller than that of the rectangular channel.

Lattice Boltzmann simulation of the effects of cavity structures and heater thermal conductivity on nucleate boiling heat transfer

The boiling heat transfer technology with cavity surfaces can provide higher heat flux under lower wall superheat,which is of great significance for the cooling of electronic chips and microelectromechanical devices.In this paper,the boiling characteristics of the cavity surfaces are investigated based on the lattice Boltzmann(LB)method,focusing on the effects of cavity shapes,sizes,and heater thermal conductivity on the heat transfer performance.The results show that the triangular cavity has the best boiling performance since it has less residual vapor and higher bubble departure frequency than those of the trapezoidal and rectangular cavities.As the cavity size increases,the enhancement of heat transfer by the cavity mouth is suppressed by the heat accumulation effect at the heater bottom.The liquid rewetting process during bubble departure is the reason for the fluctuation of the space-averaged heat flux,and the heater thermal conductivity determines the fluctuation amplitude.The evaporation of liquid in the cavity with high thermal conductivity walls is more intense,resulting in shorter waiting time and higher bubble departure frequency.

The‘New Normal’of Extreme Weather And the Urgency of Transformation“The era of global warming is over and the era of global boiling has arrived.”

Phong,a 42-year-old Vietnamese motorcyclist begins his busy day at 5 a.m.In Hanoi,light motorcycles are an important mode of transportation.Countless motorcycles shuttle through the streets and alleys of the city,transporting parcels,goods,and passengers to various destinations.Phong usually works for 12 hours straight with little rest.However,the unprecedented heat waves this summer had often pushed daytime temperatures to above 40 degrees Celsius,making it extremely difficult for Phong to complete his daily routine.Phong prepared a hat,a wet handkerchief,and more drinking water.He even installed a small umbrella above his mobile phone rack to prevent the phone from overheating in the sun because it is his only source of work.Despite all the equipment,he is still worried.“If I suffer heat stroke or anything else,I will be unable to work,”he said.“I can’t afford it.”

亚麻催化氧化与碱煮一浴脱胶工艺及其性能

使用棉纺系统进行亚麻纺纱前需经过脱胶处理,为解决传统碱脱胶工艺得到的亚麻纤维白度低和氧化脱胶时纤维易氧化受损、木质素残留造成纤维断裂伸长率低的问题,采用N-羟基-3,4,5,6-四苯基邻苯二甲酰亚胺(NHTPPI)催化氧化与碱煮一浴的方法对亚麻落麻进行脱胶,研究了pH值,反应温度以及催化剂NHTPPI、助催化剂9,10-蒽醌、双氧水、氢氧化钠质量浓度等因素对脱胶后亚麻纤维断裂强度以及白度的影响,得到了NHTPPI催化氧化与碱煮一浴亚麻脱胶的最佳工艺:pH值为10.5,反应温度为83.6℃,NHTPPI、9,10-蒽醌、双氧水、氢氧化钠质量浓度分别为0.6、0.5、10.35、5.67 g/L,此优化条件下得到的亚麻纤维断裂强度为4.39 cN/dtex,白度为70.53%。将催化氧化与碱煮一浴脱胶、高碘酸钠氧化脱胶以及传统碱脱胶与双氧水漂白3种工艺进行对比,发现3种工艺得到的纤维主体长度在28 mm左右,白度均在70%以上,但催化氧化与碱煮一浴脱胶得到的亚麻纤维断裂强度最高,处理时间最短。

大竹蛏营养组成、呈味特性和体外抗氧化活性研究

为实现大竹蛏资源的高效、综合开发利用,以大竹蛏鲜肉(fresh Solen grandis meat,FSGM)、煮肉(boiled Solen grandis meat,BSGM)和煮液(Solen grandis boiling liquid,SGBL)为研究对象,对其营养组成、呈味特性和抗氧化活性进行分析比较。结果表明,新鲜大竹蛏出肉率为79.33%,煮后质量损失率为49.89%;FSGM蛋白质含量为(11.55±0.34)%,总糖含量最低,为(0.46±0.00)%;煮后蛋白质和灰分损失最大,BSGM中蛋白质、脂肪和总糖相对含量分别为(19.33±0.33)%、(1.59±0.09)%、(0.83±0.01)%;SGBL中干物质仅占2.90%,其中41.72%为蛋白质;FSGM和BSGM中18种氨基酸总量分别为(52.15±0.50)g/100 g和(64.04±0.06)g/100 g,谷氨酸含量最高,呈味氨基酸占比分别为(47.44±0.35)%、(47.80±0.05)%,FSGM和BSGM的第一限制氨基酸均为蛋氨酸+半胱氨酸,SGBL的第一限制氨基酸为色氨酸;FSGM和BSGM中均检测出16种脂肪酸,PUFA占比分别为(36.98±0.33)%和(28.57±0.15)%,SGBL中6种脂肪酸均为饱和脂肪酸;SGBL中牛磺酸含量最高,为(2073.93±56.90)mg/kg;FSGM和BSGM中均检测到10种单糖,葡萄糖和半乳糖二者之和占比分别为51.16%、66.69%,SGBL中95.20%的单糖为葡萄糖;SGBL游离氨基酸含量最高,为(10.68±0.06)g/100 g,其中39.83%为甘氨酸。BSGM中核苷酸总量最高,为(2388.04±99.57)g/kg,其中AMP含量最高,为(380.28±10.48)mg/kg;3组样品均检测到3种有机酸,绝大部分为酒石酸;经复合蛋白酶酶解的FSGM和经风味蛋白酶酶解的BSGM抗氧化活性最强。上述结果可为大竹蛏资源的进一步开发利用提供一定的理论参考和依据。

竖直互连小通道内流动沸腾传热强化机理分析

为推动流动沸腾技术在燃料电池散热领域的应用,该文以R141b为工质,对不同流速下的并联直通道及互连小通道内流动沸腾情况进行三维瞬态数值模拟。利用换热系数、基底温度及综合换热因子等参数对比各结构的换热性能,并探究互连小通道的换热强化机理。研究表明:换热趋势随气泡行为呈周期性变化,气泡脱离时的换热效果最佳;由连通口引发的二次流促进热量传递与壁温升高,使通道可提前2 ms满足成核条件,且气泡在10^(-4) m/s以上的二次流速作用下率先脱离;五连通通道的换热系数较并联直通道可提升19.6%~23.3%,继续增加连通口数,换热系数的相对增长率均不足3.5%;涡结构使压降随连通口数增加而增大,且增势并不减弱,八连通通道的压降较并联直通道增加29.5%~42%。可见,二次流在影响气泡行为、强化换热的同时也带来压力损失,综合换热性能与连通口数目不成正相关。

熬煮条件对鸡汤中低聚肽含量和感官品质的影响

为探究熬煮条件对鸡汤品质的影响,文章使用微量双缩脲法测定鸡汤中低聚肽含量,并结合感官评分等指标探究低温煮、超声波低温煮和常压蒸煮对鸡汤品质的影响。结果表明,超声波低温煮的低聚肽含量远远高于低温煮和常压蒸煮,并且3种加工方式的低聚肽含量都呈现逐渐上升的趋势。超声波低温煮在90℃熬制3 h时低聚肽含量达到最高,为0.90 mg/mL;低温煮在90℃熬制9 h时低聚肽含量达到最高,为0.751 mg/mL;常压蒸煮在熬制3 h时低聚肽含量达到最高,为0.747 mg/mL。由感官评价结果可知,超声波低温煮在80℃熬制2 h时感官评分达到最高,为92.8分;低温煮在90℃熬制6 h时感官评分达到最高,为92.4分;常压蒸煮在熬制2 h时感官评分达到最高,为90.6分。

超低甲醛释放木质素基胶黏剂的制备及应用

针对脲醛树脂耐水、耐候性能差和潜在甲醛释放的问题,以工业碱木质素(L)为原料,通过与苯酚(P)、尿素(U)和甲醛(F)共缩聚反应制备了符合ENF级Ⅰ类胶合板要求的木质素基胶黏剂(LPUs)。考察了L、P和U质量比对LPUs凝胶时间、游离甲醛含量、储存稳定性、固化反应活性以及胶合板理化性能的影响。结果表明:mL/(mP+mU)为1∶1时制备的树脂LPU1~LPU4中,随着尿素用量的增加,LPUs树脂的凝胶时间逐渐缩短,m(P)∶m(U)=30∶70时制备的LPU4,其凝胶时间为(18±2)min,约为LPU1(m(P)∶m(U)=90∶10)的凝胶时间(30±2)min的40%,游离甲醛含量从0.05%(LPU1)升高至0.18%,储存期由127 d缩短至14 d,表现出脲醛树脂的理化特性。DSC监测固化过程焓变行为表明,LPUs树脂反应活化能仅为商业酚醛树脂和脲醛树脂的2%~7.8%。mL/(mP+mU)=1且苯酚用量不低于尿素时制备的LPU1~LPU3树脂胶合板耐沸水胶合强度和甲醛释放量满足ENF级Ⅰ类胶合板要求,其中LPU2树脂的施胶量可降低至工业生产工艺的66.7%,此时,依然可以确保胶合板的耐沸水胶合强度和甲醛释放量满足ENF级Ⅰ类要求,可有效降低胶合板生产成本。

土壤有效硼提取及测定方法比较

本文提出一种沸水浴提取–ICP-OES测定土壤有效硼的方法,并着重比较分析沸水提取–姜黄素比色法、沸水提取–ICP-OES法、沸水浴提取–ICP-OES法和沸水浴提取–姜黄素比色法对土壤有效硼的测定结果。通过讨论4种方法的测定下限、方法检出限和测定精密度及正确度,及对来自不同地区高中低有效硼含量的6种土壤有效态成分标准物质和4种实际土壤样品的测定比较,探讨4种方法分析测定的关键因素、方法相关性。结果表明,沸水浴提取–ICP-OES法操作简单便捷,方法的检测下限低、干扰因素少、重复性好,可适用于各类型批量样品分析及研究。本研究可为实验室开展土壤有效硼测定方法研究提供借鉴,也可为承担“第三次全国土壤普查”土样检测的实验室在土壤有效硼测定的方法选择、效率提升和质量保证上提供技术支撑。

高钙镁钛精矿沸腾氯化制备TiCl_(4)的热力学及动力学

针对高钙镁钛精矿难以满足沸腾氯化制备四氯化钛工艺问题,从热力学和动力学角度对高钙镁钛原料碳热还原—沸腾氯化制备TiCl_(4)工艺进行了深入研究。结果表明:钛精矿高温碳热还原历程为:FeTiO_(3)→TiO_(2)+Fe→Ti_(n)O_(2) n-1(n=4~9)+Fe→Ti_(3)O_(5)+Fe→Ti_(2)O_(3)+Fe→TiC_(x)O_(1-x)+Fe,碳氧钛生成的温度必须高于1400℃,此时钛精矿中的Ca、Mg、Al、Si、Mn等杂质元素在1800℃以内都不会被还原为对应的碳化物;高钙镁钛铁矿精矿碳热还原制备碳氧钛过程中,失重率随温度升高呈现4阶段上升,其中阶段1和3分别为受扩散控制生成金属Fe和碳氧钛的快速失重段,而阶段2和4分别为金属Fe和碳氧钛形核长大的缓慢失重阶段,4个阶段的表观活化能分别为49.84、-2.24、12.82、-2.53 kJ mol。沸腾氯化过程还原产物中的Fe、MgO和CaO均会优先被氯气氯化,但当存在TiO_(2)时,SiO_(2)和Al_(2)O_(3)则不易被氯化,碳氧钛较适宜沸腾氯化的温度为300~650℃,沸腾氯化前5分钟为还原产物中碳氧钛的快速氯化阶段,主要受表面化学反应的控制,而后5~20分钟为Ti_(2)O_(3)的缓慢氯化阶段,主要受颗粒内部扩散控制的影响。

不同压力蒸煮对中国菰米淀粉结构及理化特性的影响

以中国菰米淀粉为原料,利用扫描电镜、X射线衍射仪、傅里叶红外光谱仪检测在常压蒸煮、高压蒸煮条件下菰米淀粉的晶体结构,并分析其热稳定性、凝沉特性及消化特性,探究其在不同条件处理下晶体结构和理化性质的变化。结果表明:蒸制处理后,淀粉的表观形貌、晶体结构、短程有序性、粒径大小无显著变化,蒸制提高了淀粉的糊化峰值温度、老化程度,降低了相对结晶度和热焓值。高压处理可促进淀粉老化,利于提高淀粉抗消化性。煮制处理后,淀粉结构破损严重,晶体结构由有序向无序转变,糊化后无明显的凝沉特性,粒径显著降低。经蒸煮处理后,淀粉慢消化淀粉含量显著提升,利于维持血糖平衡。

二元堤基结构堤防管涌机理模型试验

为了科学解释二元堤基结构堤防管涌致灾机制并揭示其形成、演化过程和致溃规律,在考虑堤基强、弱透水层之间壤土过渡层作用的基础上,通过室内模型试验完整地模拟了二元堤基管涌从单个泡泉发展至管涌群并最终造成堤基塌陷溃决的全过程。试验结果表明:上部黏土及壤土层在渗流的顶托作用下向上隆起并在堤基内部产生层间水平渗漏通道,导致发生潜层砂沸,最终向上发展为表面砂沸的渗透破坏;二元堤基结构管涌发展可分为裂缝发展、潜层破坏、上覆层破坏、管涌通道上溯、堤基破坏和堤基溃决6个发展阶段;表面砂沸由潜层砂沸发展而来,潜层砂沸是由于土层内竖向坡降所引起的渗流力大于上部土体浮容重时造成的土层结构破坏所致,临界竖向坡降处于0.9~1之间;壤土层的存在会加快堤后自由边界区域管涌群的发展速度,但可以延缓管涌通道的上溯,对堤基具有保护作用。

硇砂传统炮制工艺与京帮炮制经验探讨

探讨了硇砂的传统炮制工艺以及京帮炮制的经验。硇砂临床效果显著,但由于不良反应大限制了其应用。古人对硇砂的炮制解毒进行了深入研究,包括对硇砂毒性的认识、净制法、炖法、煮法、煅制法等。京帮炮制硇砂的经验遵从古法,分为炖法与煮法两种,均属现代中药炮制的提净法。京帮醋制硇砂过程中需要注意制作的季节、所用器具、火候的控制、醋的选择等工艺细节。通过对硇砂的传统炮制工艺以及京帮炮制的经验的探讨,对硇砂的现代研究有借鉴意义。

BOG再液化工艺动态模拟教学

液化天然气(LNG)的运输储存方式主要是通过LNG运输船,由于LNG温度低,易挥发,在LNG船的液货舱中LNG与环境存在热交换,蒸发产生的闪蒸气(BOG)会使液货舱压力升高造成安全隐患。安全、环保处理BOG的方法是将其再液化为LNG重新输送回液货舱。基于此,介绍一种利用软件模拟动态的BOG液化工艺,使用再液化方法为过冷LNG喷射制冷再液化。借用软件模拟再液化工艺的流程,对工艺流程的开、停车过程进行模拟,形成了一套BOG再液化工艺的动态模拟。通过案例教学可加强学生及员工利用软件进行工艺动态模拟的能力,提高对虚拟仿真技术的掌握。

相变腔冷凝现象对沸腾-凝结共存相变传热的影响

针对平板热管均热器内部狭小空间存在着强烈的沸腾与凝结相互作用,以去离子水为工质,可视化实验研究了冷凝面上发生的凝结现象及其对相变腔传热性能的影响。通过分析冷凝面上液滴的形成、长大、汇聚成液膜、滴落,以及气液界面产生气泡随气流运动对冷凝液膜的冲刷作用,揭示了不同热流密度和充液率时相变腔冷凝面传热传质特性对沸腾-凝结共存相变传热影响的内在机理。实验结果表明:受重力影响,水蒸气在冷凝面上凝结有液滴和液膜共存并相互转化的特性,冷凝面热阻在相变腔总热阻中占比65%~88%,适宜的充液率有利于沸腾气泡冲刷冷凝壁面,加快冷凝液的回流,改善冷凝面及相变腔的传热性能;随着热流密度的增大,沸腾过程变得剧烈,冷凝面受沸腾气泡的冲刷频率提高,冷凝液回流速度加快,冷凝面热阻减小,传热性能得到提高。

针状电极作用下相分离结构逆流微细通道流动沸腾传热性能

为研究针状电极与相分离结构强化技术组合作用下微细通道流动沸腾传热性能,该研究提出了一种平行逆流微细通道热沉,针对顺流和逆流微细通道,通过高低压切换实现气相分离。以乙醇为试验工质,改性聚偏二氟乙烯多孔疏液膜(polyvinylidene fluoride,PVDF)作为气液相分离工具,在入口过冷度为10℃,有效热流密度范围为48.08~87.29 kW/m^(2)工况下开展流动沸腾试验,引入饱和沸腾传热系数传热强化因子(Fht)研究不同相分离结构孔数(4孔PSS-1、6孔PSS-2、10孔PSS-3)(phase separation structure,PSS)和不同电场强度(200、400、600 V)组合作用下的微细通道沸腾强化传热特性规律和机理。研究结果表明,在相同工况下,与普通微细通道(无相分离结构0孔PSS-0和无电场)相比,单独相分离结构和单独针状电极作用下微细通道的传热性能均得到有效提高,10孔相分离结构和600 V电场强度分别作用时的最大Fht为1.14和1.20,相分离结构和针状电极组合作用下微细通道传热性能得到进一步提升,10孔和600 V电场强度组合条件下的最大Fht为1.29,结果表明相分离结构和针状电极2种强化技术存在一定的协同效果。研究结果为微尺度复合强化沸腾传热技术提供参考。