Study of filament performance in heat transfer and hydrogen dissociation in diamond chemical vapor deposition

Hot-filament chemical vapor deposition ( HFCVD) is a promising method for commercial production of diamond films. Filament performance in heat transfer and hydrogen decomposition in reactive environment was investigated. Power consumption by the filament in vacuum, helium and 2% CH4/H2 was experimentally determined in temperature range 1300℃-2200℃. Filament heat transfer mechanism in C-H reactive environment was calculated and analyzed. The result shows that due to surface carburization and slight carbon deposition, radiation in stead of hydrogen dissociation, becomes the largest contributor to power consumption. Filament-surface dissociation of H2 was observed at temperatures below 1873K, demonstrating the feasibility of diamond growth at low filament temperatures. The effective activation energies of hydrogen dissociation on several clean refractory flaments were derived from power consumption data in literatures. They are all lower than that of thermal dissociation of hydrogen revealing the nature of catalytic dissociation of hydrogen on filament surface. Observation of substrate temperature suggested a weaker role of atomic hydrogen recombination in heating substrates in C-H environment than in pure hydrogen.

Analysis and design of resistance-wire heater in MOCVD reactor

Metal organic chemical vapor deposition(MOCVD) is a key equipment in the manufacturing of semiconductor optoelectronic devices and microwave devices in industry. Heating system is a vital part of MOCVD. Specific heating device and thermal control technology are needed for each new reactor design. By using resistance-wire heating MOCVD reaction chamber model, thermal analysis and structure optimization of the reactor were developed from the vertical position and the distance between coils of the resistance-wire heater. It is indicated that, within a certain range, the average temperature of the graphite susceptor varies linearly with the vertical distance of heater to susceptor, and with the changed distances between the coils; furthermore, single resistance-wire heater should be placed loosely in the internal and tightly in the external. The modulate accuracy of the temperature field approximately equals the change of the average temperature corresponding to the change of the coil position.

THE INFLUENCE OF THE DRAWING TEMPERATURE ON PHYSICAL STRUCTURE AND PROPERTIES OF PET FILAMENTS

In this paper the influences of the drawing temperature on physical structures and properties of PET filaments have been studied. The results show that the temperatures of the first-stage drawing will have significant effects on birefringence development of filaments during the second stage drawing, as well as the oriented amorphous filaments change to crystanine-oriented filaments after heat treatment. Increasing temperature of the second-stage drawing can be greatly increasing the crystallinity and decreasing the dry heat shrinkage of the filaments.

Lyocell长丝热定型工艺对其结构性能的影响

针对Lyocell长丝热定型工艺尚不明确的问题,采用干喷湿纺技术制备Lyocell水洗丝,研究热定型张力、温度和时间等工艺参数对Lyocell长丝力学性能和尺寸稳定性的影响,并结合广角X射线衍射、小角X射线散射以及双折射率等测试分析了不同条件下长丝结晶、取向以及微孔等结构的变化规律,阐明了热定型条件下长丝结构与性能的关系。结果表明:温度为110~130℃时,3 min的热定型可保证长丝中水分的去除,在热定型过程中长丝的晶区结构基本不变,微孔尺寸的减小以及非晶区纤维素分子链段的收缩,提高了长丝的致密化程度并降低了取向程度;施加0.5~2.3 cN/dtex的张力,长丝的断裂强度、初始模量不易发生弱化,且干热收缩率低于0.7%。施加适当张力的热定型有效抑制了非晶区链段的解取向,保持了纤维高结晶、高取向的结构特点,从而保证了Lyocell长丝的力学性能和尺寸稳定性。

Effects of nano-metal oxide additives on ignition and combustion properties of MICs-boron rich fuels

Boron has been considered a promising powdered metal fuel for enhancing composite propellants'energy output due to its high energy density.However,the high ignition temperature and low combustion efficiency limit the application of boron powder due to the high boiling point of the boron oxide layer.Much research is ongoing to overcome these shortcomings,and one potential approach is to introduce a small quantity of metal oxide additives to promote the reaction of boron.This study prepared boron-rich fuels with 10 wt%of eight nano-metal oxide additives by mechanical ball milling.The effect of metal oxides on the thermo-oxidation,ignition,and combustion properties of boron powder was comprehensively studied by the thermogravimetric analysis(TG),the electrically heated filament setup(T-jump),and the laser-induced combustion experiments.TG experiments at 5 K/min found that Bi_(2)O_(3),MoO_(3),TiO_(2),Fe_(2)O_(3),and CuO can promote thermo-oxidation of boron.Compared to pure boron,Tonsetcan be reduced from 569℃to a minimum of 449℃(B/Bi_(2)O_(3)).Infrared temperature measurement in T-jump tests showed that when heated by an electric heating wire at rates from 1000 K/s to 25000 K/s,the ignition temperatures of B/Bi_(2)O_(3) are the lowest,even lower than the melting point of boron oxide.Ignition images and SEM for the products further showed that the high heating rate is beneficial to the rapid reaction of boron powder in the single-particle combustion state.Fuels(B/Bi_(2)O_(3),B/MoO_(3),and B/CuO)were mixed with the oxidant AP and ignited by laser to study the combustion performance.The results showed that B/CuO/AP has the largest flame area,the highest BO_(2) characteristic spectral intensity,and the largest burn rate for powder lines.To combine the advantages of CuO and Bi_(2)O_(3),binary metal oxide(CBO,mass ratio of 3:1)was prepared and the test results showed that CBO can very well improve both ignition and combustion properties of boron.Especially B/CBO/AP has the highest burn rate compared with all fuels containing other additives.It was found that multi-component metal-oxide additive can more synergistically improve the reaction characteristics of boron powder than unary additive.These findings contribute to the development of boron-rich fuels and their application in propellants.

石墨烯烯丝绒与羽绒的性能对比

对比石墨烯烯丝绒和羽绒的保温性能、压缩回弹性、防钻绒性、蓬松度、远红外发射率、远红外温升、静电性能和抗菌性能等指标,通过科学严谨的试验设计和数据分析,探讨石墨烯烯丝绒能否替代羽绒成为新型的保暖填充材料的可行性。

150 kV逆变电源性能优化及其束源特性

为了进一步提高电子束流发生系统工作的可靠性和稳定性,提高电子束加工质量,采用AC-DC-AC-DC-AC-DC的拓扑电路、新型功率变压器、高压脉冲检测技术、优化的束流反馈控制与灯丝加热电流闭环反馈控制技术等,分别优化了高压加速电源、偏压电源与灯丝加热电源。将所研制逆变电源与150 k V/30 k W电子枪、真空系统等组成了一套电子束流发生系统,测试了该电子束流发生系统输出的高压、最大束流以及灯丝加热电流、偏压变化对束流输出的影响。试验结果表明:经过优化的逆变电源高压输出达到-150 k V,高压输出线性度较好,最大束流达到200 m A;高压、灯丝加热电流给定时,随着偏压降低,束流输出逐渐增大;高压、偏压给定时,随着灯丝加热电流增大,束流输出存在死区、线性增大区和恒流区。

PTT与PBT长丝的热水收缩性能比较

测试并分析了不同温度下PTT与PBT的DTY长丝的热水收缩率,结果表明PTT的热水收缩率明显小于PBT,而且前者在100℃时表现出最大收缩率,而PBT则要在更高的温度才会达到。

PET/PTT双组分弹性长丝的热收缩性能及卷曲形成机理探讨

由于纺丝线上PET/PTT复合长丝中各组分受到的纺丝张力差异导致两组分存在潜在的热收缩性差异。从纺丝线下来的成品丝只有通过后道热处理,才能有效释放潜在的热收缩差异,获得理想、可用的卷曲弹性。通过TMA测试了PET/PTT双组分复合弹性长丝及其对应单组分纤维的热收缩性能。同样的外作用力下,PET/PTT纤维的收缩应变更接近PET纤维、远小于PTT纤维。同样预张力约0.2N下,PET/PTT、PET、PTT纤维的收缩应力依次变大。结果表明PET纤维具有较小的收缩应力和较小的收缩应变,PTT纤维具有较大的收缩应力和较高的收缩应变。这导致后道热处理过程中,PTT组分发生强烈的尺寸收缩,并带动收缩较小的PET组分位于纤维外侧并形成更为细密的卷曲。

固定床中丝状颗粒的传热传质特性

目前对于固定床中丝状填充颗粒传热传质特性的认识仍处于初始阶段。为了能够从颗粒尺度的微观层面揭示丝状颗粒与气体、颗粒与颗粒之间的热、质传递机理,建立了一种丝状颗粒传热传质数学模型,之后将离散单元法与计算流体力学相结合,对实验中较难获得的床层局部流动及传递信息进行了数值模拟,并着重分析比较了气流入口温度以及表观气速等关键因素对固定床中丝状颗粒温度和含水率变化的影响规律。通过模拟结果与实验数据的对比,验证了所建模型的可行性。研究结果表明:同一时刻,固定床中颗粒温度大体上是随着床层高度的增加而降低,含水率则是随着床层高度的增加而升高;气流入口温度对于固定床中丝状颗粒平均温度的提升起着主导作用,而颗粒的传质速度则受表观气速的影响更为明显。

丝状颗粒在滚筒横向截面中的传热传质特性

针对丝状物料在滚筒内干燥不均等问题,从干燥机理出发,建立了一种基于离散单元法的丝状颗粒传热传质数学模型.利用该模型对滚筒横向截面中丝状物料的温度和含水率的变化过程进行了分析计算,并通过实验验证了数学模型的有效性.研究结果表明:筒壁温度的变化对丝状颗粒传热传质特性有着直接且重要的影响;在干燥的初始阶段,颗粒彼此间温度的不均匀性迅速增大,但随着干燥的进行,颗粒之间的温度差别又呈现出逐渐缩小的趋势.颗粒间含水率的不均匀性在干燥的初始阶段同样迅速增大,当满足一定的干燥条件或一定的干燥时间,筒体内部丝状颗粒的干燥程度将会越来越均匀;丝状颗粒在滚筒中所获取的热量主要来自于与高温壁面(特别是与筒体之间)的接触导热;与升举式抄板相比,均布式抄板可使颗粒在滚筒横截面上的分布及颗粒间的温度和含水率更加均匀.

热处理温度对涤纶混纤丝结晶及取向的影响

采用由同一喷丝板生产的283 dtex／48 f多异涤纶POY为原料,在平牵机上拉伸热处理制取混纤丝,研究了拉伸和热定形温度对纤维结晶和取向的影响。结果表明:随着热盘温度和热板温度的提高,涤纶混纤丝的结晶度和晶粒取向度有所提高,在热板温度较高时,热盘温度对结晶度的影响较小。混纤丝的声速取向系数随热盘、热板温度的变化表现出较复杂的关系。

基于离散单元法的丝状颗粒传热数学模型

丝状颗粒作为一类长径比较大的非球形颗粒,其传热特性及相关技术广泛应用于工农业生产的诸多领域。但目前颗粒在运动过程中传热问题的研究还很不充分,特别是对于丝状颗粒,更是缺乏有效的数学模型进行描述。从颗粒传热机理出发,提出了一种基于离散单元法的丝状颗粒传热模型,模型中综合考虑了颗粒碰撞(接触)传热、颗粒的内部导热以及颗粒与气体间的对流换热。利用该模型,对固定床中堆积丝状颗粒的热量迁移过程进行了数值模拟,着重比较了各种传热方式对传热过程的影响。研究表明,对流换热对整体传热量的贡献较大。此外,还获得了不同工况下颗粒温度随时间的变化规律。

改性氰酸酯纤维缠绕工艺研究

本文采用环氧树脂改性氰酸酯树脂，研究出适用于纤维湿法缠绕的低粘度并具有较高耐热性能的改性树脂体系。通过试验研究确定了树脂体系的纤维湿法缠绕工艺，对改性树脂与碳纤维复合材料的力学性能进行了研究，并进行了标准容器爆破试验。研究结果表明：改性氰酸酯树脂体系的粘度小（420mPa·S，25℃），并具有较长使用期（30小时以上），完全适用于湿法缠绕工艺。使用改性氰酸酯体系缠绕的标准容器，其纤维方向复合材料性能相当于环氧树脂体系缠绕的容器，并且具有较高的玻璃化转变温度（Tg=232℃），与现有的环氧树脂体系相比，玻璃化转变温度提高了30％～40％。

可加热纬编针织物的电热性能

为开发可加热纬编针织服装,采用衬纬方式将导电丝织入针织物中,并对其电热性能进行测试和分析。分别将单根、2根、3根镀银长丝和单根不锈钢长丝衬入到针织物中,测试导电纱线的最大负载电流、织物的热稳定性、织物的电热升温特性和表面温度的均匀性。结果显示:不锈钢长丝的最大负载电流最大,其次是3根镀银长丝的;通电后,衬入镀银长丝织物的电阻变化率较小;衬入3根镀银长丝的织物通电后温度升高的速度较快,且达到稳定工作的温度较高;测试范围内,织物的稳定温升与输入电压成正比;织物表面温度均匀性较好。认为可选择衬入3根镀银长丝的纬编织物制作可加热针织服装。

影响高功率光导开关临界频率热因素的数值分析

基于时域有限差分法(FDTD)对非线性模式面结构砷化镓光导开关的热传导过程进行了数值模拟。研究了光导开关临界频率与电流丝位置、半径、数量、芯片尺寸、环境温度等参数的关系。研究表明:临界频率随电流丝半径、数量的增加,呈指数上升趋势;临界频率随着电流丝深度、芯片厚度的增加,呈指数下降趋势;临界频率在一定范围内随环境温度的增加呈线性下降趋势。

岛津3200X-BTCD球管灯丝加热电路原理分析及故障维修

本文通过一款岛津多功能X线诊断系统不产生X射线的故障现象,从分析球管灯丝加热电路原理入手,经过异常检测电路排查和实际测量,最终找到并解决了mA-POWER-UD电路板Q3损坏的故障。该类故障的技术解决,需要维修人员熟悉X光机的基本结构和原理,具备良好的观察力和电路分析能力,养成良好的维修习惯,练就举一反三、融会贯通的综合能力。

CEg基体及其纤维缠绕复合材料耐热性能研究

针对纤维缠绕的特点,对氰酸酯(CE)树脂进行了改性(改性后的氰酸酯树脂称为CEg基体),改性的目的是不仅使CE树脂适合纤维缠绕工艺,而且不降低纯CE树脂及其复合材料的耐热性能。通过实验摸索出适合纤维缠绕工艺的CEg基体配方及其工艺参数、固化参数。用SEM(扫描电镜)研究了T700/CE以及T700/CEg复合材料的剪切断口形貌;用TG/DTA研究了氰酸酯树脂改性前、后的复合材料热分解温度;用DSC研究了CE和CEg基体的玻璃化温度。研究结果表明:CEg基体最显著的特点是不仅使纤维缠绕工艺和固化工艺简单易行,而且不降低纯氰酸酯树脂及其复合材料的耐热性能。改性后的氰酸酯树脂可以充分发挥氰酸酯树脂的耐高温优势,这是本研究的特点,达到了预期的效果。

阴极热丝组件中辐射换热量的改善

采用辐射换热的网络法分析和计算间热式阴极组件辐射的热耗散,并通过高温计测温、近距离平板二极管试验证实了理论模型的准确性。理论分析表明,在两板间插入一块与其发射率相同的遮热板后,两板之间的辐射换热量将减少为原来的二分之一。通过电工理论的基尔霍夫定律计算表明,对于直径为Ф10 mm,高为8 mm的阴极组件,辐射换热损失为7.32W;实验表明,阴极底部增加一层黑度较小的热屏底盖后,辐射换热量平均为3.05 W,约为加热屏底盖前辐射换热量的41.7%。阴极底部增加二层热屏底盖后,实际辐射换热平均约为1.82 W,约为加热屏底盖前辐射换热量的24.9%。所以在相同条件下,阴极底部增加热屏底盖后消耗功率比敞开结构小得多。在阴极组件外增加热屏罩,在理论上辐射换热量将减少为原来的35%。实验中辐射换热量约为3.5 W,占加热屏罩前辐射换热量的47.6%。这是因为没有考虑组件其它热量的散失,所以实际辐射换热量大于理论计算值。在阴极底部增加一层热屏底盖后,再在阴极组件外增加热屏罩的遮热效果比阴极底部增加二层热屏底盖要好。

纤维缠绕成型聚酰亚胺基复合材料性能研究

以第2代聚酰亚胺(Polyim ide-Ⅱ,PI-Ⅱ)为基体,采用纤维缠绕成型工艺制作了T700/PI-Ⅱ(碳纤维/Polyim ide-Ⅱ)、S2/PI-Ⅱ(高强玻璃纤维/Polyim ide-Ⅱ)复合材料。研究了纤维缠绕成型PI-Ⅱ复合材料的界面性能和耐热性能。采用扫描电镜(SEM)研究了T700/PI-Ⅱ以及S2/PI-Ⅱ复合材料的剪切断口形貌,用于分析PI-Ⅱ复合材料的界面性能;采用TG/DTA 6300热分析仪测定T700/PI-Ⅱ以及S2/PI-Ⅱ复合材料的热分解温度,用于研究T700/PI-Ⅱ以及S2/PI-Ⅱ复合材料的耐热性能。本文研究也包括S2/PI-Ⅱ复合材料在300℃高温的层间剪切强度保留率。研究结果表明:T700/PI-Ⅱ复合材料在空气氛围中的起始热分解温度(TID)为549℃,S2/PI-Ⅱ复合材料为542℃。S2/PI-Ⅱ复合材料在300℃高温的层间剪切强度保留率为72%。