UAV flight test of plasma slats and ailerons with microsecond dielectric barrier discharge

Plasma flow control（PFC） is a promising active flow control method with its unique advantages including the absence of moving components, fast response, easy implementation, and stable operation. The effectiveness of plasma flow control by microsecond dielectric barrier discharge（μs-DBD）, and by nanosecond dielectric barrier discharge（NS-DBD） are compared through the wind tunnel tests, showing a similar performance between μs-DBD and NS-DBD. Furthermore, theμs-DBD is implemented on an unmanned aerial vehicle（UAV）, which is a scaled model of a newly developed amphibious plane. The wingspan of the model is 2.87 m, and the airspeed is no less than 30 m/s. The flight data, static pressure data,and Tufts images are recorded and analyzed in detail. Results of the flight test show that the μs-DBD works well on board without affecting the normal operation of the UAV model. When the actuators are turned on, the stall angle and maximum lift coefficient can be improved by 1.3° and 10.4%, and the static pressure at the leading edge of the wing can be reduced effectively in a proper range of angle of attack, which shows the ability of μs-DBD to act as plasma slats. The rolling moment produced by left-side μs-DBD actuation is greater than that produced by the maximum deflection of ailerons,which indicates the potential of μs-DBD to act as plasma ailerons. The results verify the feasibility and efficacy of μs-DBD plasma flow control in a real flight and lay the foundation for the full-sized airplane application.

Thickness measurement approach for plasma sprayed coatings using ultrasonic testing technique

The special ultrasonic testing system has been developed for thickness measurement of plasma sprayed coatings. The ultrasonic immersion method was used to obtain stable coupling condition and avoid other disadvantages of contact method. Spherical acoustic lens were designed to focus ultrasonic beam so as to improve beam directivity and concentrate ultrasonic energy. To increase testing precision and avoid mussy wave signals, moderate pulse width and frequency of the transducer has been selected. The displacement of transducer in X-Y-Z directions was precisely manipulated by step-controlled system to insure the accuracy of focus length and repetition of measurement. Optimized testing conditions (with the transducer of center frequency of 10 MHz and crystal diameter of 8 mm, focus length of 9.5 mm, diameter of focal column of 0. 1 mm and length of focal column of 0.27 mm) were selected to determine the thickness between 285 -414 μm of ZrO2 coatings plasma sprayed on the nickel based superalloy. The frequency interval of the periodic extremums in ultrasonic power spectra decreases with increasing coating thickness. The ultrasonic results accord with those of metallographical method.

Characterization of microstructure and strain response in Ti-6Al-4V plasma welding deposited material by combined EBSD and in-situ tensile test

Additive layer manufacturing （ALM） of aerospace grade titanium components shows great promise in supplying a cost-effective alternative to the conventional production routes. Complex microstructures comprised of columnar remnants of directionally solidifiedβ-grains, with interior inhabited by colonies of finerα-plate structures, were found in samples produced by layered plasma welding of Ti-6Al-4V alloy. The application of in-situ tensile tests combined with rapid offline electron backscatter diffraction （EBSD） analysis provides a powerful tool for understanding and drawing qualitative correlations between microstructural features and deformation characteristics. Non-uniform deformation occurs due to a strong variation in strain response between colonies and across columnar grain boundaries. Prismatic and basal slip systems are active, with the prismatic systems contributing to the most severe deformation through coarse and widely spaced slip lines. Certain colonies behave as microstructural units, with easy slip transmission across the entire colony. Other regions exhibit significant deformation mismatch, with local build-up of strain gradients and stress concentration. The segmentation occurs due to the growth morphology and variant constraints imposed by the columnar solidification structures through orientation relationships, interface alignment and preferred growth directions. Tensile tests perpendicular to columnar structures reveal deformation localization at columnar grain boundaries. In this work connections are made between the theoretical macro- and microstructural growth mechanisms and the observed microstructure of the Ti-6Al-4V alloy, which in turn is linked to observations during in-situ tensile tests.

Progress on the ultrasonic testing and laser thermography techniques for NDT of tokamak plasma-facing components

During manufacturing and operation, different kinds of defects, e.g., delamination or surface cracks, may be generated in the plasma-facing components (PFCs) of a Tokamak device. To ensure the safety of the PFCs, various kinds of nondestructive testing (NDT) techniques are needed for different defect and failure mode. This paper gives a review of the recently developed ultrasonic testing (UT) and laser thermography methods for inspection of the delamination and surface cracks in PFCs. For monoblock W/Cu PFCs of divertor, the bonding quality at both W-Cu and Cu- CuCrZr interfaces was qualified by using UT with a focus probe during manufacturing. A noncontact, coupling-free and flexible ultrasonic scanning testing system with use of an electromagnetic acoustic transducer and a robotic inspection manipulator was introduced then for the in-vessel inspection of delamination defect in first wall (FW). A laser infrared thermography testing method is highlighted for the on-line inspection of delamination defect in FW through the vacuum vessel window of the Tokamak reactor. Finally, a new laser spot thermography method using laser spot array source was described for the online inspection of the surface cracks in FW.

Salt spray corrosion test of micro-plasma oxidation ceramic coatings on Ti alloy

Ceramic coatings were prepared on Ti-6Al-4V alloy in NaAlO2 solution by micro-plasma oxidation （MPO）. The salt spray tests of the coated samples and the substrates were carded out in a salt spray test machine. The phase composition and surface morphology of the coatings were investigated by XRD and SEAM. Severe corrosion occurred on the substrate surface, while there were no obvious corrosion phenomena on the coated samples. The coatings were composed of Al2TiO5 and a little α-Al2O3 and mille TiO2, and the salt spray test did not change the composition of the coatings. The weight loss rate of the coatings decreased with increasing MPO time because of the increase in density and thickness of the coatings. The surface morphology of the coatings was influenced by salt spray corrosion test. Among the coated samples, the coating prepared for 2 h has the best corrosion resistance under salt spray test.

Comparative analysis of the effects of gunpowder and plasma ignition in closed vessel tests

This paper presents the results of a comparative investigation into the effects of the ignition method on the ballistic properties of a single-base gun propellant,as determined via closed vessel tests.Conventional gunpowder ignition and plasma jet ignition methods were used,and differences in the ignition time were analysed.The influence of the ignition method on the dynamic vivacity is discussed.It is shown that this influence is significant in the first phase of the combustion process,and with respect to the low values of the loading density.In the second phase of the combustion process,and for large values of the loading density,the dynamic vivacity plots for the two ignition methods converge.Regarding the burning law,close values of the exponent were obtained for the two ignition methods.The dynamic vivacity plots determined for plasma ignition reveal stronger dependence on the loading density than those determined for gunpowder ignition.The conclusion is that plasma ignition is not a solution to the problems inherent to the process of determining the ballistic properties of propellants,which results in deviation of the burning process from the geometric burning law.

Characterization of Oxygen Plasma Modified Polyimide Fibers Interfacial Adhesion Performance by Single Fiber Fragmentation Test

The application of polyimide( PI) fibers in the field of composite materials has been limited because of their smooth surface and chemical inertness. In order to overcome these problems,oxygen plasma was used to modify the surface of fibers. The single fiber fragmentation test( SFFT) was used to characterize the interfacial adhesion performance of PI fiber as a simple and accurate analysis method. It was found that the interfacial shear strength between the fiber and resin after oxygen plasma modification was increased by 54% compared to the untreated fiber. Meanwhile, the surface micromorphology,chemical composition, wettability of fibers and the interface morphology at the fiber fracture were analyzed by field emission scanning electron microscope( FESEM), X-ray photoelectron spectroscopy( XPS),contact angle measurement and polarizing microscope,respectively. All of these results demonstrated that the single fiber fragmentation test for analyzing the interfacial adhesion of PI fibers was effective.

Resistance and Reactance of Monopole Fields Induced by a Test Charge Drifting Off-Axis in a Cold and Collisional Cylindrical Plasma

We study the interaction of a uniform, cold and collisional plasma with a test charged particle moving off-axis at a constant speed down a cylindrical tube with a resistive thick metallic wall. Upon matching the electromagnetic field components at all interfaces, the induced monopole electromagnetic fields in the plasma are obtained in the frequency domain. An expression for the plasma electric resistance and reactance is derived and analyzed numerically for some representative parameters. Near the plasma resonant frequency, the plasma resistance evolves with frequency like a parallel RLC resonator with peak resistance at the plasma frequency pe, while the plasma reactance can be capacitive or inductive in nature depending on the frequency under consideration.

兽用化学药品血药浓度法生物等效性试验注册资料技术评审要点及常见问题

生物等效性试验作为兽药获批上市的关键试验,其研究过程和技术评审都要遵循特定的法规和指导原则。以药动学参数为终点的血药浓度法生物等效性试验是目前普遍采用的研究方法,适用于药物活性成分吸收进入体循环具有全身作用的剂型(大多数内服剂型和特殊注射剂)。本文根据生物等效性定义、相关法规和指导原则,结合近年来新兽药注册资料,对血药浓度法生物等效性试验资料的技术评审要点及常见问题进行梳理,旨在为新兽药的研发和注册提供参考。

基于小冲杆试验的纯钨韧脆转变温度测定及其变形特性

在不同温度(25,200,300,400,500℃)下对纯钨进行小冲杆试验,获得断裂能与温度之间的关系,拟合得到纯钨的韧脆转变温度;对不同温度小冲杆试验后的纯钨断口形貌进行观察,探究纯钨在小冲杆试验中的变形特性。结果表明:在25,200℃下纯钨处于完全脆性状态,在300℃下处于半脆性状态,而当温度达到400℃后,纯钨表现出良好的塑性;在250~400℃范围内纯钨的断裂能急剧升高,拟合得到的韧脆转变温度为(342±8)℃。当温度低于韧脆转变温度,纯钨断口存在沿轧制方向的长直裂纹,断裂特征随温度升高由沿晶断裂向穿晶断裂转变;当温度高于韧脆转变温度,断口出现帽形挤出形貌以及环形裂纹和短缺口裂纹,并且环形裂纹处存在大量韧窝,断裂特征为韧性断裂,且短缺口裂纹处出现钨分层现象。

TC4钛合金样品硬度对激光诱导等离子体温度的影响研究

钛合金具有密度小、强度高、耐腐蚀等优良特性,目前已被广泛应用于压气机盘和叶片制造等航空制造领域。然而,钛合金材料的硬度较低,在服役过程中极易出现摩擦损耗等问题,从而降低部件的使用寿命。因此,原位、实时的硬度监测对钛合金部件在使用过程中的性能评估具有重要意义。本工作利用激光诱导击穿光谱(LIBS)对TC4钛合金样品热处理后的不同硬度进行了表征。实验结果发现,随着样品硬度增大,材料的激光诱导等离子体温度呈上升趋势,表明激光诱导等离子体温度可以作为金属硬度的重要表征参数。研究还进一步探究了材料硬度变化对等离子体温度影响的内在机理。

河北省免费NIPT联合PAPP-A、F-β-HCG 及超声检查诊断孕中期胎儿染色体异常的意义

目的 评价河北行免费的无创产前DNA检测(NIPT),联合血清妊娠相关血浆蛋白-A(PAPP-A)、游离β-人绒毛膜促性腺激素(F-β-HCG)检测及超声对孕中期染色体异常的诊断价值。方法 选取衡水市第二人民医院2019年1月至2023年1月接收的3 591例拟行染色体检测的孕中期妇女,均行免费NIPT联合血清学指标(PAPP-A、F-β-HCG)及超声检查。将羊水穿刺染色体核型分析结果记为金标准,采用受试者工作特征曲线(ROC)评价不同方法诊断孕中期染色体异常的价值。结果 经随访,在3 591例中,共有39例染色体异常,其中,32例经超声检查有染色体异常,34例经NIPT检测有染色体异常。在3 552例染色体正常的胎儿中,34例经超声检查有染色体异常,36例经NIPT检测有染色体异常;染色体异常胎儿的母体PAPP-A、F-β-HCG水平均高于染色体正常胎儿的母体(P<0.05)。PAPP-A、F-β-HCG共同诊断胎儿染色体异常的敏感度及ROC曲线下方的面积(AUC)均高于母体PAPP-A、F-β-HCG单独诊断(P<0.05);NIPT,PAPP-A、F-β-HCG及超声的联合诊断的敏感度及AUC均高于NIPT,PAPP-A、F-β-HCG,超声的单独诊断(P<0.05),且不同方法诊断染色体异常的特异度对比差异均无统计学意义(P>0.05)。结论 孕中期胎儿染色体异常的母体PAPP-A、F-β-HCG水平高,且NIPT联合PAPP-A、F-β-HCG及超声诊断染色体异常有较好的价值。

妊娠期糖尿病患者血糖水平异常对母婴结局的影响

目的探讨孕期血糖异常变化与妊娠期糖尿病(GDM)患者出现妊娠期高血压(HDP)及妊娠结局的关系。方法通过75 g口服葡萄糖耐量试验来观察孕产妇的特征;血糖升高引起的不良妊娠结局及新生儿的结果;空腹血糖水平和餐后血糖水平、药物干预治疗与巨大儿(LGA)和妊娠期HDP之间的关系。结果305例GDM孕妇中,159例孕妇(52.13%)空腹血糖(FPG)升高,146例(47.87%)餐后1 h和2 h血糖升高。在FPG升高的GDM孕妇中LGA和HDP分别占24.50%和14.50%;在餐后血糖水平升高的GDM孕妇中LGA和HDP分别占9.60%和6.20%。患有GDM的孕妇中,包含空腹血糖升高的3个级别水平需要药物治疗的孕妇比其他级别水平血糖升高的孕妇多,差异有统计学意义(P<0.05)。FPG升高对GDM孕妇HDP和LGA有更高的风险,差异有统计学意义(P<0.01)。药物治疗GDM孕妇,LGA的风险更大,差异有统计学意义(P<0.05)。结论GDM孕妇的FPG升高比餐后血糖升高更能预测LGA和高血压妊娠结局。

碱熔-电感耦合等离子体质谱法测定铌钽矿中铌钽锂铍

这是一篇矿物分析测试领域的论文。建立了碱熔-电感耦合等离子体质谱法同时测定铌钽矿中铌钽锂铍的快速测定方法。采用过氧化钠:氢氧化钠=1:1的混合熔剂分解样品,水提取使铌钽等元素完全形成沉淀,与液体分离,采用10%硫酸+10%过氧化氢溶液25 mL转化沉淀和溶液后用电感耦合等离子体质谱仪测定样品中铌、钽、锂、铍元素的含量。采用该方法测定国家一级标准物质GBW 07153、GBW 07155、GBW 07185,各元素的测定值与认定值基本一致,相对误差为0.50%~4.77%,相对标准偏差(n=6)为-0.009%~0.008%,适用于铌钽精矿、难分解或复杂样品中铌钽等元素的测定,并在生产实践中进行了应用。

电感耦合等离子体质谱仪在线稀释进样系统设计及其便捷测定氢甲酰化反应液中钴和磷元素

为了快速测定氢甲酰化反应有机相中钴和磷元素的浓度,对电感耦合等离子体质谱仪(ICP-MS)进样系统进行改造,实现直接对有机相进行分析.使用反应溶剂对待测物料进行在线自动稀释,然后直接进样测试元素的含量.样品的稀释倍数由进样泵参数进行校准,测试结果与手动稀释的误差低于3%.改进后的ICP-MS可以及时监测氢甲酰化反应过程中钴和磷浓度,发现实际生产过程中产能不足的问题,进一步指导促进增产的具体应对方案.

AB血浆倍比稀释在高效价自身抗体患者抗体筛查中的应用研究

目的探讨用AB血浆倍比稀释是否可替代盐水法进行同种抗体效价检测,并消除高效价自身抗体影响,检出同种抗体。方法选取四组标本进行检测:①6例自身抗体标本;②16例已知同种抗体的标本;③16例同种抗体+自身抗体混样标本(人为将6例自身抗体血浆和16例同种抗体血浆混合配成);④4例自身抗体且分别存在抗-C、抗-E、抗-Jka、抗-cE的受血者标本。对①②③组标本分别用盐水、AB血浆分别进行倍比稀释,用抗人球蛋白试验(微柱法)测效价,对④组标本用AB血浆稀释,用抗人球蛋白试验(微柱法)进行不规则抗体筛查。结果①组6例自身抗体标本用盐水倍比稀释法,效价均≥512,用AB血浆倍比稀释法,效价均≤4;②组仅一例效价为2的抗-M结果不一致,盐水稀释法为2,AB血浆稀释法为4,效价≥4时两者结果一致;③组用盐水法与AB血浆稀释法,在效价≥16时,两种方法结果无差异。效价<16时,盐水倍比稀释后效价均为16;AB血浆稀释法,同种抗体效价≥8时,可检出与原同种抗体效价一致,效价≤4时无法分辨同种抗体和自身抗体。④组分别存在抗-C、抗-E、抗-Jka、抗-cE抗体的四个含有自身抗体的受血者在AB血浆倍比稀释试验中,在1∶8效价试管中出现符合相应抗体筛查反应格局变化。结论在高效价自身抗体存在时盐水倍比稀释法极高,AB血浆倍比稀释法能消除1∶4效价试管后自身抗体的影响;AB血浆为倍比稀释液不影响同种抗体的效价检测,且略优于盐水倍比稀释法;AB血浆倍比稀释在高效价自身抗体存在的情况下,可根据三系抗体筛查格局的不同变化检出效价≥8的同种抗体存在,是一种较为简单的可避免自身抗体干扰的免疫血液学实验方法。

TP2铜管精整工序喷墨质量不良原因分析及改进措施初探

在精密铜管精整复绕工序中,涡流探伤装置检测到伤点后会向喷墨装置发送信号,以对铜管表面缺陷进行喷墨标记,但是该过程普遍存在喷墨不良,严重影响了对缺陷的判断。本文介绍了TP2铜管生产线中涡流探伤仪器的工作原理,对原有的涡流探伤仪器、喷墨装置以及喷枪结构进行调研,分析了原有喷墨装置喷墨时存在的漏墨和拖墨问题,探讨了等离子技术与激光刻蚀技术作为喷墨技术替代方案的可能性。文献调研、现有技术分析及其他替代试验的结果表明,采用等离子体表面处理技术对已喷墨铜管进行处理后,可以一定程度地改善铜管拖墨的问题;采用功率为300 W的激光对铜管表面进行刻蚀处理,激光头速度分别为80 mm/s和200 mm/s时,对铜管表面刻蚀呈现出的不同效果,均能够进行缺陷的有效标识。因此,铜管表面激光刻蚀技术可以作为喷墨技术的替代方案。

驱梅汤联合多西环素对梅毒患者免疫炎症反应及外周血单核细胞TLR2、Foxp3 mRNA的影响

目的探讨驱梅汤联合多西环素对梅毒患者免疫炎症反应及外周血单核细胞(PBMCs)Toll样受体2(TLR2)、叉头框蛋白3(Foxp3)mRNA水平的影响。方法选取2016年12月至2020年12月邢台市第二医院收治的107例梅毒患者作为研究对象。采用随机信封法分为常规组(n=53)和实验组(n=54)。常规组采用多西环素治疗,实验组采用多西环素联合驱梅汤治疗。比较两组梅毒滴度快速血浆反应素试验(RPR)转阴率、临床疗效、T淋巴细胞亚群(CD3^(+)、CD4^(+)、CD4^(+)/CD8^(+))、PBMCs TLR2、Foxp3 mRNA相对表达量及不良反应发生情况。结果实验组治疗后3、6个月RPR转阴率高于常规组(P<0.05);实验组总有效率高于常规组(P<0.05);治疗30 d后实验组CD3^(+)、CD4^(+)、CD4^(+)/CD8^(+)高于常规组(P<0.05);治疗30 d后实验组PBMCs TLR2、Foxp3 mRNA相对表达量低于常规组(P<0.05);实验组不良反应发生率低于常规组(P<0.05)。结论驱梅汤联合多西环素治疗梅毒患者能提高转阴率,疗效确切,且安全性较高,这可能与抑制PBMCs TLR2、Foxp3 mRNA表达有关。

低压等离子喷涂NiCoCrAIYTa涂层的抗燃气热冲击性能研究

为了保障涡轮叶片材料的抗高温氧化与耐热腐蚀性能,采用低压等离子喷涂技术在航空发动机涡轮叶片试验件上成功制备了NiCoCrAlYTa涂层。通过对不同粉末制备的NiCoCrAlYTa涂层进行1000℃/75 h燃气热冲击试验,研究了带涂层叶片尺寸、涂层表面形貌、相组成和显微组织、涂层厚度和均匀性等性能参数的变化。结果表明:热冲击试验后,不同涂层叶片的整体尺寸未发生显著变化,表明涂层在高温环境下具有稳定的尺寸;涂层表面形成了Al_(2)O_(3)膜和NiAl_(2)O_(4)尖晶石,保留了较好的结构完整度,这有助于提高涂层的耐腐蚀性能;涂层的物相组成主要包括γ-Ni、γ’-Ni_(3)Al和少量的β-NiAl,形成了贫Al区、互扩散区、二次反应区等典型微区结构,析出的TCP相为R相,表明在热冲击过程中涂层发生了相变;不同粉末制备的NiCoCrAlYTa涂层均表现出了良好的抗热冲击性能,为航空发动机涡轮叶片的高温应用提供了可行的涂层方案。