Influence and sensitivity analysis of thermal parameters on temperature field distribution of active thermal insulated roadway in high temperature mine

To study active heat insulation roadway in high temperature mines,the typical high temperature roadway of−965 m in Zhujidong Coal Mine of Anhui,China,is selected as prototype.The ANSYS numerical simulation method is used for sensitivity analysis of heat insulation layer with different thermal conductivity and thickness,as well as surrounding rock with different thermal conductivity and temperature on a heat-adjusting zone radius,surrounding rock temperature field and wall temperature.The results show that the heat-adjusting zone radius will entirely be in the right power index relationship to the ventilation time.Decrease in thermal conductivity and increase in thickness of insulation layer can effectively reduce the disturbance of airflow on the surrounding rock temperature,hence,beneficial for decreasing wall temperature.This favourable trend significantly decreases with ventilation time,increase in thermal conductivity and temperature of surrounding rock,heat-adjusting zone radius,surrounding rock temperature field,and wall temperature.Sensitivity analysis shows that the thermal physical properties of surrounding rock determine the temperature distribution of the roadway,hence,temperature of surrounding rock is considered as the most sensitive factor of all influencing factors.For the spray layer,thermal conductivity is more sensitive,compared to thickness.It is concluded that increase in the spray layer thickness is not as beneficial as using low thermal conductivity insulation material.Therefore,roadway preferential consideration should be given to the rocks with low temperature and thermal conductivity.The application of the insulation layer has positive significance for the thermal environment control in mine roadway,however,increase in the layer thickness without restriction has a limited effect on the thermal insulation.

Risks of non-conservative design according to ASME B31.1 for high-temperature piping subjected to long-term operation in the creep range

This study investigates the risks of non-conservative piping design according to ASME B31.1 for hightemperature piping subjected to long-term operation at high temperature in a creep regime based on a sensitivity analysis of the hold time. Design evaluations of hightemperature piping were conducted over a range of hold times in the creep regime according to ASME B31.1,which implicitly considers the creep effects, and the French high-temperature design code of the RCC-MRx, which explicitly considers the creep effects. Conservatisms were quantified among the codes in terms of the hold times. In the case of B31.1, the design evaluation results do not change depending on the hold time at high temperature,whereas in the case of RCC-MRx, they do. It was shown that the design limits of RCC-MRx were exceeded when the hold time exceeded certain values, whereas those of B31.1 were satisfied regardless of the hold times. Thus, the design evaluations according to B31.1 did not consistently yield conservative results and might lead to non-conservative results in the case of long-term operations in the creep range.

Isolated Solid-State Packaging Technology of High-Temperature Pressure Sensor

The principle of miniature isolated solid-state encapsulation technology of high-temperature pressure sensor and the structure of packaging are discussed, including static electricity bonding, stainless steel diaphragm selection and rippled design, laser welding, silicon oil infilling, isolation and other techniques used in sensor packaging, which can affect the performance of the sensor. By adopting stainless steel diaphragm and high-temperature silicon oil as isolation materials, not only the encapsulation of the sensor is as small as 15 mm in diameter and under 1 mA drive, its full range output is 72 mV and zero stability is 0.48% F.S/mon, but also the reliability of the sensor is improved and its application is widely broadened.

EFFECT OF HYDROGEN ON HIGH TEMPERATURE PLASTICITY OF Ti-6Al-4V ALLOY

The effects of various hydrogen contents on the flow stress(σ),strain rate sensitivity expo- nent(m)and the tensile elongation(δ)of Ti-6Al-4V alloy were studied.The microstructure of the alloy was also investigated.The results indicate that,a suitable amount of hydrogen in the alloy can reduce the flow stress in the temperature range 800—860℃. Consequently,the superplastic temperature can be decreased and the ductility improved.

Tunable and highly sensitive temperature sensor based on graphene photonic crystal fiber

Optical fiber temperature sensors have been widely employed in enormous areas ranging from electric power industry,medical treatment,ocean dynamics to aerospace.Recently,graphene optical fiber temperature sensors attract tremendous attention for their merits of simple structure and direct power detecting ability.However,these sensors based on transfer techniques still have limitations in the relatively low sensitivity or distortion of the transmission characteristics,due to the unsuitable Fermi level of graphene and the destruction of fiber structure,respectively.Here,we propose a tunable and highly sensitive temperature sensor based on graphene photonic crystal fiber(Gr-PCF)with the non-destructive integration of graphene into the holes of PCF.This hybrid structure promises the intact fiber structure and transmission mode,which efficiently enhances the temperature detection ability of graphene.From our simulation,we find that the temperature sensitivity can be electrically tuned over four orders of magnitude and achieve up to~3.34×10^(-3) dB/(cm·℃)when the graphene Fermi level is~35 meV higher than half the incident photon energy.Additionally,this sensitivity can be further improved by~10 times through optimizing the PCF structure(such as the fiber hole diameter)to enhance the light–matter interaction.Our results provide a new way for the design of the highly sensitive temperature sensors and broaden applications in all-fiber optoelectronic devices.

高灵敏度SiC动态高温压力传感器仿真研究

为了提高碳化硅(SiC)动态高温压力传感器的灵敏度,采用p型SiC材料,同时对传感器的敏感单元的不同结构———方膜和圆膜,利用Ansys软件进行了静力学仿真与分析,并完成了敏感芯片的尺寸设计。仿真结果表明:优化后的传感器输出灵敏度为14.2μV/(V·kPa)。在100~600℃内非线性误差小于1.53%。动态仿真表明:传感器的固有频率为481kHz,传感器可以在160kHz高频环境中安全工作,该结果为进一步制备SiC高温压力传感器奠定了理论支撑。

耐高温丙烯酸酯压敏胶研究进展

由于丙烯酸酯压敏胶耐高温性能不足而在诸多应用领域受到限制,近年来行业中涌现了诸多通过改性提升其耐温性的研究。本文对近年来有关丙烯酸酯压敏胶耐高温改性的研究工作进行了综述,对耐高温性能的测试方法进行了汇总和比较,对交联剂及交联方式研究、有机硅改性、丙烯酰胺化合物改性、含氟化合物改性、杂环类耐热单体改性等多种改性方法进行了分析和总结。最后,对耐高温丙烯酸酯压敏胶的发展方向进行了展望。

含双温敏单体的耐220℃高温降失水剂

针对目前油井水泥降失水剂高温条件下耐温性差的问题,通过分子结构设计,以丙烯酰胺(AM)、对苯乙烯磺酸钠(SSS)、双温敏单体N,N-二甲基丙烯酰胺(DMAA)与N,N-二乙基丙烯酰胺(DEAA)为原料,通过水溶液自由基聚合法制备了一种耐高温降失水剂(LHF-1L)。以失水量为评价指标,对合成条件进行了优选,同时对LHF-1L进行了结构表征和性能评价。结果表明,在AM、SSS、DMAA、DEAA物质的量比为4∶6∶2∶0.5,引发剂为单体总质量0.75%的过硫酸钾(KPS)溶液,反应物溶液pH值为7,反应温度为65℃,反应时间为4 h的条件下制得的LHF-1L的降滤失性能最佳。在220℃、7%加量下的失水量为42 mL。FT-IR、TG和GPC测试结果表明,4个单体均成功参与聚合并生成目标产物。当温度达到273℃后,LHF-1L才出现明显的热损失,其多分散系数为1.396,数均分子量为171 351 g/mol。此外,LHF-1L对水泥浆流动度和水泥石抗压强度发展的影响较小。在220℃下,在水泥浆中加入7%LHF-1L后的失水量仍能控制在50 mL以内。在150℃、94.4 MPa下,LHF-1L不会使水泥浆急剧增稠和超缓凝,稠化曲线正常,未发生异常胶凝现象。采用双温敏单体制备LHF-1L,增强了其在高温下的温敏疏水缔合作用,从而提高了高温降滤失性能,可以满足高温条件下的固井技术需求。

基于压力衰减法的低渗透储层高温敏感性评价实验

低渗透油气藏在钻完井过程中易受到损害且难以解除,而利用传统的稳态驱替法评价低渗透储层损害存在适用性差及实验效率低等技术局限。为此,基于压力脉冲衰减法基本原理,分析了上游压力衰减规律及其与岩心渗透率的关系,以岩心损害前后压力脉冲衰减时间为评价指标,建立了适用于低渗透储层损害评价的实验设备与方法,并利用渤海湾盆地渤中凹陷深部低渗透砂岩岩心,开展了室温和150℃高温条件下的敏感性实验。研究结果表明:(1)当实验条件一定时,压力衰减时间仅与岩心的渗透率有关,压力脉冲衰减法可在无需计算渗透率的情况下对低渗透岩心的损害程度进行评价;(2)实验设备组成简单且操作便捷,避免了复杂的渗透率计算及其带来的误差,实验所需时间远低于常规的稳态法且可重复性良好,在低渗透气藏、特低渗透及超低渗透油藏具有很好的适用性;(3)高温环境明显加剧了储层的敏感性损害,深部高温储层损害特征及技术对策研究需要充分考虑高温的影响。结论认为,该认识解决了传统低渗透储层敏感性评价方法适用性差的难题,为高温低渗透储层保护技术对策研究提供了实验方法支撑和理论依据。

高温界面接触热阻试验

飞行器组件之间不可避免地存在接触热阻,接触热阻的准确获取对热结构细节设计至关重要。针对高温、高压同时作用下接触热阻测量的难题,基于静态热流法自主研制了高温界面接触热阻测量装置。该装置能够有效测得给定界面压力、最高热面温度1500℃固体结构界面间的接触热阻。利用该装置,成功开展了三类热结构组件高温界面接触热阻测量试验,获得了压力、温度和界面粗糙度对结构界面接触热阻的影响规律。试验结果表明,测量装置稳定可靠、温度和压力载荷模拟精度高、试验易实施,试验结果可以为飞行器热结构设计与工程应用提供依据。

一种基于S型电磁超材料的高温温度传感器设计

针对目前超材料温度传感器存在的量程小且灵敏度较低的问题,设计了一种碳氮化硅基的S型超材料的高温传感器。通过CST电磁仿真软件对超材料温度传感器进行模拟仿真,在其他结构参数一定的情况下,对金属条的长度、宽度、厚度、条间隙及基板厚度等参数进行了设计与优化,确定了传感器结构的最佳尺寸,同时分析了传感器的谐振频率对温度的影响。结果表明,在28℃~1000℃下平均灵敏度可达5.674 MHz/℃。与之前报道的高温传感器相比,灵敏度提高了5倍,这种高灵敏度温度传感器可为航空发动机、武器装备等系统中的高温测试提供一种技术手段。

碳纤维增强聚碳酸酯复合材料在高温中的准静态压缩强度

选择碳纤维平纹织物、碳纤维单向布分别和聚碳酸酯制备热塑性复合材料,包括碳纤维增强聚碳酸酯平纹层合板、单向板和正交层合板,并自制的高温装置与MTS(Material Testing System)搭配使用,研究上述三种复合材料在20℃、120℃、150℃、180℃四种温度下的面外准静态压缩行为,分析结构和温度对性能的影响,探究不同条件下的失效模式。结果表明:碳纤维增强聚碳酸酯平纹层合板的最大应力值和压缩模量与正交层合板接近,均高于碳纤维增强聚碳酸酯单向板;且温度对三种复合材料的面外准静态压缩性能有很大影响,随温度升高,准静态压缩模量和最大应力值都减小。

轴向应变放大式谐振温度传感器研究

试验机专用改装系统成为开展民机适航、审定试飞的重要手段之一。为进一步提升系统性能,满足高精度高可靠性要求,该文提出一种基于轴向应变放大结构的谐振式温度传感器。基于应变放大结构建立频率-温度模型,推导频率温度系数作为衡量灵敏度的物理量。为降低理论模型与仿真模型的相对误差,该文进行仿真分析与误差修正,将二者误差降低至0.5%。测试结果表明,当外界温度在273~293 K范围内变化时,器件的频率温度系数为13104×10^(−6)K^(-1),仿真结果为12935×10^(−6)K^(-1),二者相比,相对误差为1.3%。与以往谐振式温度传感器比较,相对灵敏度最大提高了83倍。该结构可用于高灵敏度谐振式温度传感器的优化设计,满足试验机改装系统的应用需求。

立方大腔体静高压装置中叶腊石的传压及密封性能研究

本文基于高压研究及超硬材料生产所用的静高压立方大腔体(六面顶)压机的需要,制备了源于南非叶腊石矿的两种(A和B)叶腊石粉压块,并与同工艺国产(北京门头沟)黄色叶腊石粉压块进行比较,以此建立评估叶腊石传压及密封性能的实验方法与物理判据.采用Bi,Tl,Ba等标压物质原位标定了以上3种叶腊石压腔中心位置及密封边处的压力;同时,采用银熔点法分别获得了3种叶腊石作传压密封材料时高温下腔体压力与系统加载的对应关系.结果表明,在相同加载油压下南非叶腊石B粉压块和国内叶腊石粉压块中心位置的压力差值不超过0.1 GPa,在升压和降压过程中叶腊石块中心位置与密封边位置的压力差值也更为相近.相比于南非叶蜡石A粉压块,B粉压块在高温传压和密封性能上更接近国产叶腊石粉压块.

超致密储层流体敏感性实验方法

超致密储层具有基块致密、黏土矿物丰富等特点,潜在流体敏感性强,准确评价储层流体敏感程度对优选入井工作液性能至关重要。选取超致密气层砂岩岩心,改进了压力衰减法评价储层流体敏感性,并与常规的压力衰减法和改进的稳态流体敏感性实验方法对比分析。结果显示,常规的压力衰减法样品水敏程度为中等偏弱,改进的压力衰减法评价样品水敏程度中等偏强,实验结果与改进的高温高回压测试方法具有一致性,且实验时间缩短近40%。分析认为:改进的压力衰减法能够模拟地层高温环境,原理清楚,结果可靠,新方法弥补了常规压力衰减法工作流体无法高效注入岩心的不足,提高了测试精度,缩短了实验时间,对优化致密油气藏储层损害评价方法具有借鉴意义。

南缘超高压致密气藏应力敏感及钻井液污染研究

储层低渗特征和钻井液污染是影响低渗气藏有效建产的主要因素。基于耐超高温高压实验系统和CT扫描技术研究了新疆油田南缘区块1个高温超高压致密气藏(158.6℃,146 MPa)渗透率应力敏感性以及钻井液污染特征。研究结果表明,1)储层岩芯孔隙中90%以上为粒间孔,且少量粒间孔被方解石胶结物和沥青全充填半充填;2)在净应力110 MPa下,所考察的两块柱塞岩芯(0.0019 mD,0.0325 mD)的应力敏感渗透率降低率(相对于储层实际净应力下)分别为39.28%和16.04%,属于中等偏弱和弱敏感;3)定性和定量表征了另外两柱塞块岩芯(0.0042 mD,0.0290 mD)在实际操作工况下钻井液侵入特征,发现钻井液均没有突破两块岩芯长度,侵入渗透率为0.0290 mD岩芯的深度为3.86 cm,但引起的表皮系数达到6.54,表现为严重污染。研究成果对于掌握高温超高压气藏储层特征、钻井液污染认识以及后续储层保护措施建立提供了重要技术支持。

基于微纳光纤谐振环的温度传感器研究

该项工作制作并验证了基于微纳光纤结型谐振环的高灵敏度且扩大测量范围的温度传感器。在微纳光纤谐振环中产生多个模式并参与谐振,多个模式谐振的光谱相互叠加,形成带包络的游标光谱。通过提取游标光谱的包络线,实现高灵敏度的温度测量,灵敏度高达-10 nm/℃。但计算得到利用游标光谱时的温度测量范围仅约为4℃。为解决测量范围过小的问题,将包络光谱与单一频率组分对应的谐振光谱相结合,使测量范围扩大至约20℃。相比于单一频率组分对应的谐振光谱,利用游标包络光谱实现了灵敏度约1600倍的放大。该方案利用游标效应提高温度测量灵敏度的同时,利用单一频率组分对应的谐振光谱扩大了游标光谱的温度测量范围,提高了传感器的性能和实用性。

高温环境下的传声器校准技术研究

为确保航空发动机高温环境下噪声测量的准确性,并提供准确溯源证明,文章开展高温环境下传声器校准技术研究,基于电阻丝加热和谐振原理建立高温环境下传声器校准装置,通过比较法对被校传声器开展溯源研究。试验结果表明:该方法在声源频率250 Hz高温环境下,灵敏度校准偏差值较小且重复性良好,可以有效实现高温环境下传声器的校准,弥补了目前高温环境下传声器无法溯源的缺陷,为航空发动机噪声测量提供可靠的计量保障。

红色荧光粉CaWO_(4)∶Eu^(3+),Bi^(3+)的制备和光学性能的研究

本文采用高温固相法合成了一系列红色荧光粉CaWO_(4)∶Eu^(3+),Bi^(3+)。通过X射线衍射仪、扫描电子显微镜和荧光分光光度计等手段,对样品的晶体结构、微观形貌、光学性能、能量传递方式、荧光寿命和热稳定性进行了表征。结果表明,当Eu^(3+)和Bi^(3+)的掺杂浓度分别为7%和2%时(摩尔分数),荧光粉红色发光(615 nm)最强,理论计算得到荧光粉的平均颗粒尺寸为50.27 nm,这与电子显微镜观察结果相符合。能量传递方式以电偶极-电四极相互作用为主,对CaWO_(4)∶7%Eu^(3+),yBi^(3+)(y=0~6%)系列荧光粉进行了荧光寿命测量,发现它们荧光寿命基本相同,都在0.56 ms左右。对CaWO_(4)∶7%Eu^(3+),2%Bi^(3+)荧光粉在不同温度下的光谱进行比较,并且计算相应的色度坐标,当温度升高时,色度坐标整体左移,发光强度有所变弱,但整体来说热稳定性较好。较好的热稳定性和明亮红光发射表明该荧光粉可以作为潜在商用红光荧光粉。

无芯片RFID高温传感器设计

设计了一种用于高温环境实时监测的基于开口环谐振器(SRR)的无芯片射频识别(RFID)传感器。传感器由双开口圆环谐振结构和氧化铝(Al_(2)O_(3))陶瓷基板构成,尺寸为25 mm×25 mm×0.5 mm。其工作原理是:Al_(2)O_(3)陶瓷基板作为温度敏感材料,具有耐高温的特性,而且介电常数随温度变化而改变,使得整只传感器谐振频率偏移,建立起温度与谐振频率之间的关系,实时监测谐振频率即可获知实时温度。仿真结果表明:设计的温度传感器可以实现200~1000℃监测,对应谐振频率从6.64 GHz下降至6.26 GHz,偏移380 MHz,传感器灵敏度0.475 MHz/℃表现很好,证明了传感器的谐振频率和温度之间存在着准线性关系。设计的无芯片RFID传感器具有无线无源、制作成本低和尺寸小等优点,非常适合应用于高温环境温度检测。