NACA00系列翼型的VAWT效能影响因素分析

采用滑移网格技术对不同参数下的小型垂直轴叶轮瞬态流场进行了数值计算,着重研究了不同安装角、翼型、叶片弦长、叶片数对叶轮功率的影响,得出不同转速下使叶轮获得最大功率的最佳翼型、叶片安装角、弦长和叶片数,并通过吹风实验验证了最佳叶片数和最佳弦长时的垂直轴风力机具有较优的气动性能。

Dynamic Circulation Control for a Vertical Axis Wind Turbine using Virtual Solidity Matching

Vertical Axis Wind Turbines (VAWTs) with fixed pitch blades have a limited power capture performance envelope as the Tip Speed Ratio (TSR) changes. Circulation Control (CC) has been proposed and simulated to possibly increase power capture of a VAWT using constant CC jet momentum, but a practical method of minimizing CC usage has yet to be explored. In addition, VAWTs are typically limited in power capture performance either by a maximum peak at a small set of TSR or wide operating TSR at fractions of the peak performance based on the design solidity. Both the reduced jet usage and solidity limitation were addressed by developing a method of dynamically using CC to perform a virtual solidity change. The developed method described within this work used CC to change blade aerodynamics to specifically match a maximum performing static solidity or wake shape at a given TSR. Simulation results using an existing aerodynamics model indicated a significant reduction in the re-quired CC jet momentum compared to a constant CC system along with control over power capture for a CC-VAWT.

Effects of Rotor Solidity on the Performance of Impulse Turbine for OWC Wave Energy Converter

Impulse turbine, working as a typical self-rectifying turbine, is recently utilized for the oscillating water column（OWC） wave energy converters, which can rotate in the same direction under the bi-directional air flows. A numerical model established in Fluent is validated by the corresponding experimental results. The flow fields, pressure distribution and dimensionless evaluating coefficients can be calculated and analyzed. Effects of the rotor solidity varying with the change of blade number are investigated and the suitable solidity value is recommended for different flow coefficients.

H-VAWT设计参数对其叶尖损失的影响

为了探讨在H-VAWT叶片上增加叶尖小翼或增大展弦比对风力机整体气动性能的作用和影响,计算和分析研究了不同设计参数对其叶尖损失的影响.首先以有限展长H-VAWT的气动性能为基准,将无限展长H-VAWT与之相比较所得到的气动性能的相对差值来分析设计参数—实度和翼型对其所生成的H-VAWT叶尖损失的影响,又通过比较不同展弦比所生成的H-VAWT的气动性能,分析总结了展弦比对H-VAWT叶尖损失改进的效果.结果表明:无论生成H-VAWT的设计参数(实度和翼型)如何,当H-VAWT工作在较高尖速比下(λ≥1.60),更适合使用改善叶尖损失的措施来改善H-VAWT的气动性能;当H-VAWT实度比较大(σ≥0.96)或生成H-VAWT的翼型较厚时,有必要增加叶尖小翼或加大叶片展弦比来减少叶尖损失的不利影响,改善H-VAWT气动性能;加大叶片展弦比对H-VAWT气动性能的改善是有限的,基于设计要求及其他几何参数的限制,H-VAWT展弦比在5≤μ≤20范围内较合适.

Wind Tunnel Test and Numerical Computation on Ice Accretion on Blade Airfoil for Straight-bladed VAWT

To invest the condition of ice accretion on the blade used for straight-bladed vertical axis wind turbine （SB-VAWT）, wind tunnel tests were carried out on a blade with NACA0015 airfoil by using a small simple icing wind tunnel. Tests were carried out at some typical attack angles under different wind speeds and flow discharges of a water spray with wind. The icing shape and area on blade surface were recorded and measured, Then the numerical computation was carded out to calculate the lift and drag coefficients of the blade before and after ice accretion according to the experiment result, the effect of icing on the aerodynamic characteristics of blade were discussed.

VAWT的抗台风研究

提出了一种可抗台风的垂直轴风力机,分析了垂直轴风力机抗台风的工作原理,叶片可随风速自行向内折叠一定角度,在正常发电的同时达到抗台风目的,安全环保,可有效节约化石燃料资源。

Effect of Impeller Solidity on the Generating Performance for Solar Power Generation

According to current solar power research,both the generating unit’s minimum start-up speed and power generation system’s minimum flow rate for operation decrease with the increase in the impeller solidity.Ideally,a high solidity should be achieved,as this translates more power for a solar power system in the start-up and shut-down cycles.However,increasing the number of blades does not increase the impeller solidity;therefore,there is an optimal number of blades needed to achieve the preferred solidity.This paper begins by selecting the blade airfoil and then performs a theoretical analysis based on the relationship between the blade number and chord length.Experiments are conducted to measure the starting and stopping wind speeds and power characteristics for different numbers of blades.The results show that a maximum impeller solidity of 0.2862 is achieved,as well as the minimum flow speed at the start-up,and the maintenance of the solar chimney power generation system is optimized when there are four blades.

Sino-Russian Strategic Cooperative Partnership: Heading for Road of Solidity

Since the independence of Russia, Sino-Russian relations have been develop-ing all along in a progressive momentum. At present, the two countrieshave established the "21st century-oriented strategic cooperative partnership of e-quality and mutual trust". Serving the basic interests of both sides with solid po-litical basis, the state relationship of this new type has proved to be the bestchoice of the Chinese and Russian people for the further development of bilateralties in the 21st century. Its major characteristics are as follows: A. Strategic cooperative partnership is established on the basis of the com-prehensive and gradual development of the Sino-Russian relations.

Effect of wind fluctuating on self-starting aerodynamics characteristics of VAWT

The present work deals with an investigation of the self-starting aerodynamic characteristics of VAWT under fluctuating wind. In contrast to the previous studies, the rotational speed of the turbine is not fixed, the rotation of the turbine is determined by the dynamic interaction between the fluctuating wind and turbine. A weak coupling method is developed to simulate the dynamic interaction between the fluctuating wind and passive rotation turbine, and the results show that if the fluctuating wind with appropriate fluctuation amplitude and frequency, the self-starting aerodynamic characteristics of VAWT will be enhanced. It is also found that compared with the fluctuation amplitude, the fluctuation frequency of the variation in wind velocity is shown to have a minor effect on the performance of the turbine. The analysis will provide straightforward physical insight into the self-starting aerodynamic characteristics of VAWT under fluctuating wind.

基于网络度量元的Solidity智能合约缺陷预测

针对现有智能合约缺陷预测方法未考虑合约代码内部结构对缺陷产生的影响的不足,提出了一种基于网络度量元的Solidity智能合约缺陷预测方法。首先,通过Solidity-Antlr4工具构建Solidity智能合约的抽象语法树(abstract syntax tree, AST);其次,根据抽象语法树构建合约网络,网络中的节点代表函数和属性,边代表函数间的调用关系和函数对属性的操作关系;然后,引入复杂网络领域的知识,构建了一套针对Solidity智能合约的网络度量元;最后,基于多种回归模型和分类模型构建智能合约缺陷预测模型,进而比较不同类型的度量元在Solidity智能合约缺陷预测方面的性能。数据实验表明,结合了网络度量元的缺陷预测模型的预测性能比相应没有结合网络度量元的模型要好。

基于Solidity的低代码以太坊微博系统的设计与实现

文章介绍了基于Solidity的低代码区块链以太坊微博系统的设计与实现。传统微博系统存在中心化管理、数据安全性和透明性不足等问题。为了解决这些问题,笔者开发了基于区块链技术的微博系统。该系统利用智能合约和Solidity编程语言实现了去中心化的微博管理,并提供了简化的用户界面和交互。系统具备基本的微博功能,如文章发布、评论和点赞。通过实现这个低代码区块链微博系统,读者能够更好地理解Solidity和以太坊的应用,并为开发类似的应用程序提供参考。

基于CFD-DEM的流-固耦合数值建模方法研究进展

随着土体渗流侵蚀研究的逐渐深入,对土颗粒流失和变形破坏机理的研究方法呈现出多尺度的特点。其中,计算流体力学-离散元耦合方法(CFD-DEM)为在细观尺度上研究流-固耦合相互作用对土体宏观力学特性的影响提供了一种行之有效的方法。针对CFD-DEM耦合方法在岩土工程领域应用现状,本文系统总结现有流-固耦合计算方法的优缺点,重点论述CFD-DEM耦合方法的建模策略,包括固相颗粒形状建模与粒间接触模型、流体相控制方程及参数计算方法,以及CFD-DEM耦合计算,并就相关问题进行深入探讨,最后提出了CFD-DEM耦合方法未来的发展方向。

库水作用下滑坡土体渗流与蠕变耦合试验研究

水库滑坡变形具有显著的渗流与蠕变耦合效应。为此,采用自主研发的渗流与蠕变耦合三轴试验仪,分别开展了渗流对蠕变的影响以及变形对渗流的影响试验研究,并改进GDS三轴仪完成了高精度控制和量测的渗流与蠕变耦合试验。结果表明:渗流作用下,土样体积变形随时间先逐渐增大后缓慢减小,主要原因是超孔隙水压力导致围压卸荷,使得土样产生回弹变形,但渗透压力持续作用于土体,使得土样体积持续缓慢减小;获取了渗流过程中土样体积的变化结果,分别建立了渗流开始前试样e-k(孔隙比-渗透系数)关系曲线及渗流稳定后试样e-k关系曲线,结果表明考虑变形影响的e-k关系曲线更能反映土体的流固耦合效应。研究成果可望为水库滑坡变形演化预测提供更加科学严密的理论和方法。

生防枯草芽孢杆菌Czk1固体发酵工艺条件优化

枯草芽孢杆菌(Bacillus subtilis)Czk1是一株具广谱拮抗、促生和诱导植株产生抗病性的根际益生菌。为了全面资源化利用农业废弃物中的有机养分和促进对植物土传病害的生物防治,本研究以Czk1为研究对象,以鸡粪为底肥,分别利用玉米秸秆、菌糠、椰糠堆肥为原料,采用液固两相发酵工艺,以稀释平板菌落计数法测定活菌总数和芽孢数,经过单因素和正交试验方法,明确Czk1固体发酵物料的配方、工艺参数和培养条件。得出Czk1固体发酵的最优条件:最佳原料为菌糠鸡粪堆肥,Czk1接种重量为10%,黄豆粉添加量为10%,含水量为40%,发酵温度为37℃,翻抛1次/72h,在此条件下,Czk1菌株中的芽孢活菌数量总量可以达到8.63×10^(8)CFU/g,芽孢数为8.37×10^(8)CFU/g。其次,发酵效果较佳的原料为秸秆鸡粪堆肥,Czk1接种量为10%,添加5%黄豆粉,40%含水量,发酵温度为37℃,翻抛1次/72 h,此条件下,Czk1接种菌株中的活菌数量总量可达到6.53×10^(8)CFU/g,芽孢数为5.97×10^(8)CFU/g;另外,在此配方条件下再添加30%菌糠,Czk1菌株的活菌数量总量及芽孢数分别可达到8.70×10^(8)CFU/g和6.90×10^(8)CFU/g。4种发酵生物肥原料的理化性质测定表明,其有机质含量、碳氮比均有较大差异,其中以鸡粪为原料其pH、全磷和全钾含量均最高,碳氮比最低,氮、磷、钾总含量均高于秸秆、椰糠和菌糠;秸秆为原料其电导率、有机质含量最高;椰糠为原料其全氮含量最高,菌糠为原料碳氮比最高。不同鸡粪与菌糠、秸秆及椰糠组合的生物有机肥的种子发芽指数均大于80%。因此,枯草芽孢杆菌Czk1具有良好的开发利用价值,选择合适的发酵生产条件可将农业废弃物制备出高质量的生物有机肥。

超长柔性悬挂固体充填刮板输送机异常工况表征及自主调控方法

固体充填刮板输送机是固体充填开采技术的关键装备,其高效智能化的程度制约着固体智能充填开采技术的进步,暂难突破超大采长、大功率、高可靠性的瓶颈,运行状态受地质条件、充填工艺等主控因素影响显著,异常工况自主调控问题亟待解决。总结了固体充填刮板输送机特征;构建了固体充填刮板输送机位姿形态与运输状态表征方法;通过分析异常工况的形成机理,选取异常工况判别指标,结合位姿与运输状态表征方法,给出了其空间位姿、牵引状态等异常工况判别准则与典型异常工况的调控路径,揭示了多工况状态下固体充填刮板输送机运载调控机制,提出了实时调控充填材料运输量、直线及水平程度组合的异常工况自主调控方法。全国首个260 m工作面长固体充填工程案例表明:通过异常工况自主调控,平均最大水平偏移距每减少100 mm,刮板链牵引力可减少85 kN,输送功率损耗可减少55 kW;平均最大垂直偏移距每减小100 mm时,输送功率损耗可减少7.2 kW;单位长度货载运量每减少100 kN/m,刮板链牵引力可减少31.9 kN,输送功率损耗可减少38.2 kW。所提出的异常工况自主调控方法可显著提升固体充填刮板输送机的输送效能,可助力实现固体智能充填开采。

二硒化钴电催化剂的制备及氧还原性能测试

具有高附加值的绿色环保型氧化剂——过氧化氢(H_(2)O_(2))的需求日益增加,急需发展绿色且安全的H_(2)O_(2)合成新方法。两电子氧还原反应(2e-ORR)是一种制备H_(2)O_(2)的高效方法,其中催化剂的高效率和高选择性是2e-ORR的关键。对二硒化钴(CoSe_(2))电催化剂的制备和性能测试实验进行了探索。首先,通过联氨还原法制备钴纳米粒子;然后,通过简单的固相反应并在不同温度下退火制备CoSe_(2)电催化剂;最后,通过一系列的表征方法对CoSe_(2)电催化剂的表面形貌、晶型、电化学及其稳定性等进行了研究。为2e^(-)ORR电催化剂CoSe_(2)的进一步研究和应用开发提供借鉴。

钢铁工业含锌尘泥回转窑处置技术的应用进展

钢铁冶炼过程(炼铁、炼钢)会产生大量的含锌尘泥,该尘泥不宜直接返回炼铁工序,一般以厂内长期堆存或外委等方式进行处理。随着我国钢铁企业“固废不出厂”“循环经济”“绿色制造”等新理念的深入推进,在钢铁厂内部采用新型回转窑技术直接处置含锌尘泥成为大势所趋。本文介绍了传统回转窑处置含锌尘泥技术的工艺流程,从原料、生产过程和产品特点等方面分析其不足,提出采用原料造球、多喷孔分级进风等创新技术的新型回转窑处置技术,该技术明显提高了回转窑处置能力,缓解了回转窑结圈,已相继在永锋钢铁、八一钢铁、诚钰环保等钢铁企业和环保公司稳定运行,产生了良好的经济与社会效益。该技术在多固废协同处置、热渣干式冷却等方面具备应用前景。

保温时间对钛合金板翅式换热器真空钎焊过程温度场及残余应力的影响

钛合金板翅式换热器成品率较低、残余应力较大,该文针对钛合金板翅结构真空钎焊过程开展热-固耦合建模与仿真研究,阐述了钎焊过程温度均匀性及残余应力分布特征,探明保温时间对钛合金板翅式换热器真空钎焊过程温度场及残余应力的影响机理.结果表明,板翅结构两侧温度较高,中部温度较低,延长保温时间可有效改善板翅结构的温度均匀性.残余应力均主要集中于翅片上表面与隔板背侧中部,在钎缝及夹持点处存在明显的应力集中现象,保温时间越长翅片钎缝的残余应力越小.模拟得到钛合金板翅式换热器真空钎焊中残余应力与试验结果相吻合,相对误差为5.3%,验证了该模型的准确性.

射流与气固两相流混合过程的测试与分析方法

湍流射流是气固快速反应过程中气相原料与固体颗粒的理想混合形式,采取有效的测试技术与分析方法获得射流与气固两相流的混合行为对研究反应过程具有重要意义。本文采用光纤探针技术获得了颗粒浓度动态数据,以提升管内颗粒聚团的传统分析方法为基础,结合小波分析,提出了射流与气固两相流混合过程中颗粒聚团的确定方法,并将射流影响区内气固间的瞬时接触状态分为颗粒聚团相、散式颗粒相以及未与颗粒充分混合的射流相。结合附壁射流理论,利用气体示踪技术获得的射流特征浓度分布结果,对理想条件下的射流中心线方程进行了修正,所得结果可预测气固两相流中射流的发展趋势。利用臭氧分解示踪技术,获得了原料射流与气固两相流混合过程中的局部反应结果,将其与气固动态混合特征及射流轨迹模型相结合,可分析流动参数对反应的影响。

桉木屑颗粒燃料固体桥结构构建与燃烧特性研究

在成型燃料内部构建固体桥结构可有效改善其物理品质,利用不同粒径桉木屑构建了具有固体桥结构的颗粒燃料,并进一步研究了颗粒燃料的燃烧特性。提出的构建方法为同种原料不同粒径混配成型,在电子压力机上进行了粒径(0,1 mm]原料混配粒径(4 mm, 5 mm]原料的颗粒压缩成型实验,结果显示混配量5%~10%时颗粒内部长粒径粒子的交叉缠绕,可形成适量的固体桥结构,短粒径粒子填充饱满,粒子间结合紧密。较佳的混配量为5%,颗粒具有较高的松弛密度,为1 074.79 kg/m^(3),最高的Meyer强度,为23.93 MPa,最低的比能耗,为27.06 kJ/kg,平衡含水率为11.65%,吸水速率k为0.015 3 min^(-1)。在热分析仪上进行了成型颗粒燃烧实验,颗粒燃烧过程较为平稳且有所延长,在升温速率10~40℃/min的范围内,着火温度Ti在246.60~265.00℃之间,最大失重速率(dm/dτ)_(1max)在-6.84~-29.10%/min之间,综合燃烧指数S在7.26×10^(-12)~1.09×10^(-10)min^(-2)·K^(-3)之间。在X射线荧光光谱仪上分析了颗粒灰分的元素组成,预测颗粒燃烧时具有中等或较高的结渣沾污趋势。