T-Y TUBE MODEL OF HUMAN ASCENDINGAORTIC INPUT IMPEDANCE

This paper proposed a T- Y tube model to simulate foe input impedance of arterial system. It improves and extends the asymmetric T-tube model which was firstproposed by O' Rourke[1] and developed laier by Liu et al.[2]. Based on foe asymmetricT-tube model. a T-Y tube model was proposed by adding branching tubes whichrepresem the iliac arteries.All the tubes are considered to be uniform,viscoelasticlongitudinally tethered cylindrical tubes.The upper tube terminates with a windkesselmodel, while the terminal arterioles of the lowr tube are expressed as a resistance.After proper eraluation of the parameters.the impedance of the arterial system iscalculated under normal physiological and hypertensive condition.The model canpredict impedance in good agreement with the experimentally obtained data no matterin normal physiological condition or in pathological condition In comparison with theasymmeric T-tube model,T- Y tube model is closer to anatomy structure of the human arlerial system and at the sametime much simpler than the extremely complex multiplebranching tube model Therefore it will be a valuable model in studying the influencesof various parameters on aorta impedance and ventricular-vascular coupling.

Y型管式油水分离结构分离特性仿真分析

管式油水分离技术具有占地面积小、分离效率高、成本低等优点,基于管式油水分离原理,设计一种Y型管式油水分离结构,利用Fluent数值模拟软件,采用标准k-ε湍流模型和Mixture多相流模型,对Y型管内部流场特性以及外部参数对分离效率的影响进行了研究。结果表明,Y型管对流体扰动小,内部流场特性稳定不易产生涡流,能够实现油水分离,支管与主管交汇处存在油水分离现象;油水分离效率随着油滴粒径的增大而逐渐提高,油滴粒径越大越利于油相上浮聚集在Y型管上层,能有效提高油水分离效率;入口速度对油水分离效果的影响很大,速度越大,油相上浮时间越短,Y型管的分离效率越低;分离效率随支管分流比的增大而增大,当入口速度为0.5 m/s时,分流比超过0.4后,分离效率不再增加。研究结果为油水分离提供了新思路,可为Y型管的设计提供理论参考。

补料比及反冲推头倾角对Y型管内高压成形质量的影响研究

目的解决5A02铝合金Y型管在内高压成形过程中易出现破裂和内凹缺陷的问题,以获得最佳成形质量的管件,对成形中的补料比和反冲推头倾角进行研究。方法使用内高压成形机进行实验,分析了管件的表面质量、管件壁厚分布情况,研究了补料比和反冲推头倾角对Y型管成形质量的影响。选取端面倾角大小分别为0°、13.5°、27°的反冲推头进行实验,设计了1.5∶1、2∶1、2.5∶1和3∶14组补料比进行对比分析。结果比较3种不同反冲推头成形得到的管件,通过对支管成形效果的分析,确定13.5°为最佳反冲推头倾角;补料比在1.5~2.5时可成形出Y型管,补料比为2∶1时,Y型管成形质量最好。为获得成形质量高的Y型管,需选择补料比为2∶1的加载路径和端面倾角为13.5°的反冲推头进行实验。结论采用合适的反冲推头端面倾角,既可以使Y型管获得理想高度的支管,又可有效地抑制成形中期支管出现的破裂缺陷;选择合理的补料比可以避免过渡圆角内凹缺陷,也可以改善Y型管的壁厚分布情况,进一步提升管件最终的成形质量。

6063-O铝合金Y型形管接头电磁成形

基于逆向识别结合平板电磁翻边实验建立6063-O铝合金的Johnson-Cook本构和失效判据,对比分析Y型管分离工序电磁翻边与电磁冲孔翻边复合成形两种方式下的电磁力分布、成形过程及变形特征,表明复合成形能成形出更高的支管并提高成形效率,更为有效地改善壁厚周向分布。在此基础上,进行电磁冲孔翻边复合成形实验,获得成形质量良好的Y型接头,探讨放电电压及管坯厚度对支管成形高度、端部壁厚以及贴模间隙的影响,分析成形支管轴向壁厚分布特征与典型缺陷。

Theory and Experimental Verification on Valveless Piezoelectric Pump with Multistage Y-shape Treelike Bifurcate Tubes

Among most traditional piezo water cooling systems, piezoelectric valve pumps are adopted as their driving sources. The valves in these pumps induce problems of shock and vibration and also make their structure complicated, which is uneasy to minimize and reduce their reliability and applicability of the whole system. In order to avoid these problems caused by valve structure, a novel valveless piezoelectric pump is developed, which integrates both functions of transforming and cooling. The pump’s Y-shape tree-like construction not only increases the efficiency of cooling but also the system reliability and applicability. Firstly, a multistage Y-shape treelike bifurcate tube is proposed, then a valveless piezoelectric pump with multistage Y-shape treelike bifurcate tubes is designed and its working principle is analyzed. Then, the theoretical analysis of flow resistance characteristics and the flow rate of the valveless piezoelectric pump are performed. Meanwhile, commercial software CFX is employed to perform the numerical simulation for the pump. Finally, this valveless piezoelectric pump is fabricated, the relationship between the flow rates and driving frequency, as well as the relationship between the back pressure and the driving frequency are experimentally investigated. The experimental results show that the maximum flow rate is 35.6 mL/min under 100 V peak-to-peak voltage (10.3 Hz) power supply, and the maximum back pressure is 55 mm H2O under 100 V (9 Hz) power supply, which validates the feasibility of the valveless piezoelectric pump with multistage Y-shape treelike bifurcate tubes. The proposed research provides certain references for the design of valveless piezoelectric pump and improves the reliability of piezo water cooling systems.

Analysis of the Flow Rate Characteristics of Valveless Piezoelectric Pump with Fractal-like Y-shape Branching Tubes

Microchannel heat sink with high heat transfer coefficients has been extensively investigated due to its wide application prospective in electronic cooling. However, this cooling system requires a separate pump to drive the fluid transfer, which is uneasy to minimize and reduces their reliability and applicability of the whole system. In order to avoid these problems, valveless piezoelectric pump with fractal-like Y-shape branching tubes is proposed. Fractal-like Y-shape branching tube used in microchannel heat sinks is exploited as no-moving-part valve of the valveless piezoelectric pump. In order to obtain flow characteristics of the pump, the relationship between tube structure and flow rate of the pump is studied. Specifically, the flow resistances of fractal-like Y-shape branching tubes and flow rate of the pump are analyzed by using fractal theory. Then, finite element software is employed to simulate the flow field of the tube, and the relationships between pressure drop and flow rate along merging and dividing flows are obtained. Finally, valveless piezoelectric pumps with fractal-like Y-shape branching tubes with different fractal dimensions of diameter distribution are fabricated, and flow rate experiment is conducted. The experimental results show that the flow rate of the pump increases with the rise of fractal dimension of the tube diameter. When fractal dimension is 3, the maximum flow rate of the valveless pump is 29.16 mL/min under 100 V peak to peak （13 Hz） power supply, which reveals the relationship between flow rate and fractal dimensions of tube diameter distribution. This paper investigates the flow characteristics of valveless piezoelectric pump with fractal-like Y-shape branching tubes, which provides certain references for valveless piezoelectric pump with fractal-like Y-shape branching tubes in application on electronic chip cooling.

Study on Numerical Simulation for Control of Winding Process of Thin Wall Spiral Tube

Being aimed at the inside wall wrinkling and sinking phenomenon of palladium-yttrium alloy thin wall spiral tube used for preparation of high purity hydrogen, extraction of hydrogen isotope, and purification and separation of hydrogen in the winding process, this article analyzed the reasons for above phenomena, established a numerical simulation model of winding process of above tube, using elastic-plastic Finite Element method analyzed the max. tensile stress and max. compression stress and their locations, thereby provides a theory base for the control of working forming course of thin wall spiral tube.

六斑平颜蚜蝇雄虫对雌性腺化合物的触角电位和行为反应

初步探究肉苁蓉Cistanche deserticola蛀茎蝇—六斑平颜蚜蝇Eumerus seximaculatum雌虫性腺化合物的主要成分并对其生物活性进行检测,为六斑平颜蚜蝇的生物防治提供理论依据。本研究采用气相色谱-质谱联用(GC-MS)技术对雌性腺化合物进行分析鉴定,根据雄成虫的触角电位(EAG)及行为反应对各组分进行筛选、分析及确定。在雌性腺化合物中共鉴定出31种挥发性物质,从中选取5种,设置5个浓度梯度,进行EAG测试。结果表明,雄成虫对5种物质不同浓度的EAG反应敏感性差异明显。其中,雄成虫对1μg/mL 1,4-丁二醇二甲基丙烯酸酯、100μg/mL邻苯二甲酸二异丁酯最为敏感;把对雄虫引诱率最高的1,4-丁二醇二甲基丙烯酸酯和邻苯二甲酸二异丁酯按照不同体积比混合后开展行为选择试验,结果显示,当两者比例为1∶3时,对雄虫的引诱率最高,可达60%以上。综上所述,1,4-丁二醇二甲基丙烯酸酯和邻苯二甲酸二异丁酯被认为是雌虫性信息素的重要成分,对雄虫有明显的引诱作用,为苁蓉蛀茎蝇性诱剂的开发奠定理论基础。

3种植物源物质复配对异囊地蛛的驱避作用

[目的]寻找烟田蜘蛛卵囊类异物防控新方法。[方法]采用Y型嗅觉仪法和滤纸药膜法研究3-甲基二十烷、桉油烯醇和野菊花精油3种植物源物质复配对异囊地蛛选择行为的影响。[结果]3-甲基二十烷、桉油烯醇和野菊花精油3种植物源物质不同体积比复配对异囊地蛛均具有很好的驱避作用,其中体积比8∶2∶3的驱避效果最好,达91.67%,且72 h内均有显著驱避效果。[结论]3-甲基二十烷、桉油烯醇和野菊花精油3种植物源物质复配作为高效植物源驱避剂防治烟田蜘蛛卵囊类异物具有应用前景。

细胞或高分子输送用“Y”形流管无阀压电泵的工作原理及流量特性

在泵腔上安装两支互为倒置的具有一定夹角的三通流管,组成泵腔的流入、排出口,并与压电振子、泵体及其他部件共同构成了"Y"形流管无阀压电泵。该泵无自身化学污染源及电磁污染源,也没有阀的开启过程;同时,具有极大的可微小化和集成化的结构能力;而且,在流管内产生的漩涡相对较小,有利于输送活体细胞及长链高分子。提出新型"Y"形流管无阀压电泵的结构。基于有限体积法,分别模拟锥形流管与"Y"形流管中的压力分布与速度矢量分布,证明"Y"形流管中的漩涡远小于圆锥流管中的漩涡,速度、压力的变化也较圆锥流管低。通过具体分析压电振子的振动,建立泵容积变化方程;同时建立泵流量与压电振子频率之间的关系式。最后,通过对所研究的"Y"形流管无阀压电泵进行流量试验后证明"Y"形流管无阀压电泵具有泵特性,进而证明了上述理论模型的正确性。

“Y”形流管无阀压电泵模拟与试验

对"Y"形流管无阀压电泵内部流场及泵流量特性进行了模拟及试验研究。采用CFX软件对"Y"形流管无阀压电泵泵腔内的流场特性进行了模拟分析。结果表明:"Y"形流管无阀压电泵工作时泵腔内的压强变化很小,涡旋对流体传输活体细胞及长链大分子基本无影响。实际制作了"Y"形流管无阀压电泵,并通过改变"Y"形流管的几何尺寸,研究了压电泵进出口端压差的变化规律。试验结果表明,压差随支管夹角增大而减小,并且当两支管宽的和接近主管宽时,压差值达到最小,当支管夹角为5°,宽为1.2 mm时,压差达到最大725 Pa。

“Y”形流管无阀压电泵振动分析及泵流量计算

为了解决医疗、卫生、保健领域进行细胞或高分子等输送工作的需要,研制了一种新型的压电泵——“Y”形流管无阀压电泵,并对其压电振子振动特性及泵流量计算进行了研究。介绍了“Y”形流管无阀压电泵及其流管的结构和特点;基于圆形薄板弯曲振动理论对压电振子振动进行了理论分析;然后讨论了泵及其流管内流体的流动特性,建立了泵流量方程。最后,基于有限元法对流管内流体流动状态进行了模拟,得到了正反流压强变化规律及正反流流阻。实验结果表明:理论泵流量与实验泵流量变化趋势一致,且两者最小相对误差为12%,证明了理论分析与数值模拟的有效性和正确性。

薄壁Y型三通管内高压成形起皱与开裂分析

本文针对薄壁Y型三通管在内高压成形过程中产生起皱、开裂缺陷的问题进行了相关研究.首先通过实验确定了Y型三通管在成形过程中产生典型缺陷的位置及类型;其次利用有限元方法分析了补料比对应力状态分区和典型点应力轨迹的影响;最后建立了加载路径的"内压-轴向补料"成形窗口.研究表明:补料比对应力状态有显著影响,通过调整补料比来改变应力状态,是避免起皱的有效措施.此外,本研究给出了不同实验结果在成形窗口中的对应位置,当加载路径超出成形区时,三通管件就会产生起皱或破裂的缺陷,甚至两种缺陷会依次发生.

多级“Y”型流管无阀压电泵的原理与试验验证

针对目前微流体混合器多需要外接动力源,且多数微混合器只能进行液体混合而不能输送液体的问题,提出将无阀压电泵引入微混合器领域,并研制了一种集混合与输送于一体的多级"Y"型流管无阀压电泵。首先,提出了多级"Y"型流管,进而设计了多级"Y"型流管无阀压电泵,并分析其工作原理;然后,对该无阀压电泵的流管流阻特性及泵流量进行理论分析;同时,利用有限元软件对多级"Y"型流管无阀压电泵进行了流场模拟,结果表明该压电泵具有单向传输作用。最后,制作了多级"Y"型流管无阀压电泵样机,并进行了泵流量与背压试验。试验结果显示:驱动电压峰峰值为100V,频率为16Hz时,流量达到最大,为16.2ml/min;驱动电压峰峰值为100V,频率为14Hz时,输出背压最大,约为64mm水柱。得到的试验数据证明了多级"Y"型流管无阀压电泵的有效性。

内压对Y型三通管内高压成形影响研究

利用数值模拟对Y型三通管内高压成形过程进行了研究,研究了87MPa～145MPa范围内5条不同内压的加载路径的成形过程,分析了过渡区内凹、支管高度不足等缺陷产生的原因和内压为116MPa时零件成形过程中典型位置的壁厚变化,以及内压对零件壁厚分布的影响。数值模拟结果表明,106MPa～126MPa为成形Y型三通管合适的压力区间,但不同内压成形的零件最小壁厚不同。

“Y”形流管无阀压电泵流场分析

为使'Y'形流管无阀压电泵真正应用到输血、输液等医疗、卫生诸领域,对'Y'形流管无阀压电泵进行了理论研究,建立了压电泵的控制方程,并对'Y'形流管内及整泵内的流场状态进行了模拟分析,利用有限元法及试验方法得到的'Y'形流管压强损失系数相差不大,证明了模拟结果的正确性.模拟结果表明,泵腔内压强变化很小,其流管内压强变化随支管夹角增大而趋于平缓,流管与泵腔交汇处有较小的涡漩存在,且其正反向压强损失系数均随支管夹角的增大而增大,因此,制作'Y'形流管无阀压电泵时,应采用支管夹角较大的'Y'形流管,并在流管与泵腔交叉处加工小圆以减小泵内涡漩.

补料比对Y型三通管内高压成形影响研究

对于Y型三通管,由于其结构的不对称性,内高压成形过程中左右冲头的轴向补料比对成形有较大的影响。通过实验和数值模拟,研究了补料比对Y型三通管的壁厚影响规律以及成形中产生的缺陷。结果表明:成形后零件左侧过渡区圆角处壁厚最大,右侧过渡区圆角处次之,枝管顶部壁厚最薄;增加补料比能在一定程度上改善枝管部分的壁厚减薄,但过度加大左右补料比,会使试件左侧圆角处产生内凹缺陷。

内压分布对内高压成形Y型三通管壁厚均匀性的影响(英文)

对薄壁Y型三通管的内管压成形进行研究。通过轴向补料,管材可以被推入模腔从而获得更高并且相对减薄率小的支管。但是Y型三通管的导向区较长,在内压作用下管材和模具之间会产生较大的摩擦力,使得材料难以流入支管。提出了采用多段式冲头用来改变导向区的内压分布并且减小导向区的摩擦力的方法。对铝合金Y型三通管进行内高压成形实验,采取两种方案,分别使用传统冲头和多段式冲头进行对比。对壁厚分布和减薄率分布进行研究,并对使用不同冲头的结果进行对比。

变截面“Y”型流管无阀压电泵原理及试验

根据三通全扩散/收缩流管的结构形式,设计了一种无阀压电泵——变截面"Y"型流管无阀压电泵。首先,分析了变截面"Y"型流管无阀压电泵的工作原理;然后,对变截面"Y"型流管流阻和泵流量进行理论分析,对变截面"Y"型流管进行模拟,得到流管正反向压强损失系数;最后,制作变截面"Y"型流管无阀压电泵样机,并进行流量试验。试验表明:当驱动电压为100V、驱动频率为12.4Hz时,流量达到最大,为25.7ml/min;使用定频12.4Hz改变电压,当电压为200V时,最大流量达到41.6ml/min。该组试验证明了变截面"Y"型流管无阀压电泵的有效性。

人体体循环输入阻抗的T-Y型管模型

本文提出了模拟人体体循环输入阻抗的T－Y型管模型，它是O‘Rourke[1]提出的，柳兆荣等[2]发展的非对称T型管模型的改进和推广．我们在非对称T型管基础上加添了代表人体两条腿的倒Y字型分叉管，从而形成了T－Y型模型，同时将模型中所有分支管都处理成具有纵向约束的粘弹性管，上肢终端小动脉床采用弹性腔模型，下肢终端小动脉床则采用传统的纯阻力形式．选取了适当参数值后，计算了正常生理情形下和高血压病理情形下的人体体循环的输入阻抗．结果显示理论模拟值和实测结果无论是生理情形或是病理情形都有良好的符合程度．T－Y型管模型比非对称T型管模型更接近人体体循环的生理结构．同时又比过份复杂的多重分叉管模型简单明了得多，因此在考察各种参数对升主动脉输入阴抗的影响．研究心室和血管的耦合机制中将是一个有实用价值的模型．