共查询到19条相似文献,搜索用时 166 毫秒
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为优化径向透平动叶片的结构型式,有效提高透平工作效率,本文基于Ansys-Fluent软件构建振荡水柱波能发电装置径向冲击式透平的三维瞬态全流域数值模型,通过改变透平动叶片吸力面型式,研究了正弦往复入射气流条件下动叶片厚度差异对透平扭矩、压强等参量的影响及其对透平输入系数、扭矩系数和周期平均效率等非定常性能评价参数的影响。在保证压力面型式不变情况下,研究了5种动叶片厚度分别为7 mm、13 mm、16 mm、19 mm和22 mm的透平在呼气、吸气阶段的非定常工作性能,结果表明:不同动叶片厚度的透平的非定常工作性能存在较大差异,动叶片厚度为13 mm的透平非定常工作性能最优,最大峰值效率可达47.7%。 相似文献
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威尔斯透平的特征是能工作于交变气流中。本文根据串列翼栅的风洞试验性能导出了该翼栅于交变气流中的性能,从而,工作于交变气流中的威尔斯透平就能处理为工作于单向气流中。在此基础上探讨了威尔斯透平的设计原理,如最佳效率及与获得最佳效率相适应的威尔斯透平设计方法。 相似文献
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汕尾市100kW波力电站空气透平与气室匹配设计 总被引:3,自引:0,他引:3
根据用1/15模型,在造波水槽中进行试验获得气室的Δ Pi- Q、ηA- Q、 NA- Q特性,以及用300mm透平模型,在1000mm活塞式往复流透平试验台进行试验获得的对称翼透平、双向固定导叶冲动透平和双向自调节导叶冲动透平的CP-、ηT-特性,进行了气室与三种空气透平的匹配设计。表明在设计波况下,采用1.025m的双向自调节导叶冲动透平时,ηT·ηA达50.43%;采用0.975m的双向自调节导叶冲动透平时,ηT·ηA达46.66%;采用0.975m的双向固定导叶冲动透平时,ηT·ηA达33.66%;采用1.45m对称翼透平时,ηT·ηA仅为29.9%。并对四种不同匹配方案进行了对比分析。 相似文献
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本文研究了使用引射器来提高海洋温差能热力循环效率,热力循环采用氨-水混合工质,通过对使用引射器与没使用引射器的热力循环进行数值模拟和对比分析,探究不同工质浓度、透平进口压力和温、冷海水温度对循环净输出功和热力循环效率的影响。研究结果表明,使用引射器后循环净输出功和热力循环效率都得到了提高。随着氨工质浓度的增加,循环净输出功不断增加,热力循环效率先增大后减小;随着透平进口压力的变化,循环净输出功和热力循环效率均先增大后减小;循环净输出功和热力循环效率随温海水温度的升高而升高,随冷海水温度的升高而减小。 相似文献
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研制了 30 0双向自调导叶透平试验机组 ,安装在 10 0 0活塞式往复流透平试验台上 ,对两种叶轮方案和 6种不同喷咀、扩压器进行了不同活塞行程、不同周期和不同恒定输出电压下性能试验。试验结果表明在喷咀出口角α1=2 1 5°、扩压器入口角α2 =6 5 5°和α1=2 4°、α2 =6 3°组合最佳 ,最高效率达 5 3 3% ,而且在宽广流量系数范围内 ,特别是大流量系数范围内都有较高效率。大大优于常用对称翼透平。将上下游导叶固定 ,变成双向固定导叶透平。用No 1叶轮和 6种导叶出口角组合进行试验。表明最佳导叶出口角为 2 4°~ 30°,最高效率仍达 38 5 % ,比对称翼透平仍高许多 相似文献
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分析了气动式波浪发电透平的特点、运行环境以及透平与振荡气流之间的相互作用过程,提出了描述透平稳态特性和动态特性的参数以及描述透平运动性能的特性曲线,推导得出透平的稳态最佳工作点,最后提出了透平的匹配设计方法。该设计模型的建立,对波浪透平的研究和设计具有较重要的指导意义 相似文献
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不同波况下气室输出气流功率是气动型波能转换装置的关键数据。本文对目前采用的不考虑空气压缩性的平均速度法和考虑空气压缩性的们努利方程瞬时速度法进行了分析,提出了一种根据气室内水位算出重量流量而后求出气室输出气流功率的新方法——重量流量法。指出平均速度法只能用于粗略的定性分析,不能用来作实际计算;瞬时速度法特别适用于有阀式气室不带涡轮或带纯冲动涡轮时气室性能的计算;重量流量法特别适宜用来计算无阀式气室的性能而不管是否带涡轮。 相似文献
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潮流发电帆翼式柔性叶片水轮机实验研究 总被引:5,自引:0,他引:5
潮流发电水轮机是海洋潮流能发电系统的核心组成部分.帆翼式柔性叶片水轮机是一种全新水流发电装置,叶片由柔性材料制成,在流体力作用下自动调节攻角,能充分利用流体的升力和阻力效应做功.以帆翼式柔性叶片水轮机获能系数为研究目标,采用因次分析法初步分析可能影响获能系数的因素,通过模型实验对叶片弧弦比、叶片边弦比、叶片密度与获能系数的关系进行研究.不同结构形式转子存在不同叶片弧弦比最佳值,叶片边弦比愈大,获能能力愈强;在一定范围内,叶片密度较小时,获能与起转能力强,转速波动性较大,适用于低流速工况;反之获能与起转能力弱,稳定性较好,电能质量较高,适用于高流速工况.最后提出优化方案,实验证实优化后水轮机在获能能力和发电能力上均有所提高. 相似文献
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一种自行研制的新型波浪发电装置—对向流、翼笼式、低参数透平[1]。该透平具有独特的壳体,能使叶轮在对向气流通过时作定向旋转,从而带动发电机发电。实验证明该机运转可靠、效率高,又具有结构简单、易于制造、寿命长、成本低等优点。用于海上浮标灯的波浪发电装置,与发电机匹配好,且容易起动。还阐述了波浪发电装置的效率分析与计算,以及活塞实验研究、水池模拟实验和海上实验结果。 相似文献
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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. 相似文献
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实密度是影响轮机获能特性的关键因素之一。文中以卧式轮机实密度为基变量,以其获能系数为主要考察点,对3种实密度卧式轮机进行水槽实验方案设计和水动力性能研究。实验分别对水流流速、轮机旋转角速度、主轴转矩以及功率进行测量,并对其对主轴的扭矩、轮机的获能系数以及叶片的旋转特性进行定量分析,最终证实了该卧式轮机的单一运行特性。通过绘制基于实密度的轮机转矩—转角曲线、获能系数—尖速比曲线和轮机功率—尖速比曲线,阐明了实密度影响卧式轮机获能水动力性能的规律,即其获能系数和发电功率都随着工况速比呈先增后降趋势。实密度较低轮机因浪流流失而获得能量小,但实密度过高轮机会导致叶片间湍流涌动,加速叶片失速特性而影响轮机获能。这为卧式浪流轮机结构优化提供了可靠依据和借鉴。 相似文献
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The performance of a Wells turbine with various non-uniform tip clearances was investigated using computational fluid dynamics (CFD). The investigation was performed on numerical models of a NACA0020 blade profile under steady flow conditions. The performance of turbines with uniform and non-uniform tip clearances was compared. The results were also compared with experimental results in literature. It was shown that the performance of turbine with non-uniform tip clearance is similar with that of turbine with uniform one in terms of torque coefficient, input power coefficient, and efficiency. However, the turbine with non-uniform tip clearance seems to have a preferable overall performance. An investigation on the flow-field around the turbine blade was performed in order to explain the phenomena. 相似文献
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Tidal current energy is prominent and renewable. Great progress has been made in the exploitation technology of tidal current energy all over the world in recent years, and the large scale device has become the trend of tidal current turbine (TCT) for its economies. Instead of the similarity to the wind turbine, the tidal turbine has the characteristics of high hydrodynamic efficiency, big thrust, reliable sealing system, tight power transmission structure, etc. In this paper, a 1/5th scale horizontal axis tidal current turbine has been designed, manufactured and tested before the full scale device design. Firstly, the three-blade horizontal axis rotor was designed based on traditional blade element momentum theory and its hydrodynamic performance was predicted in numerical model. Then the power train system and stand-alone electrical control unit of tidal current turbine, whose performances were accessed through the bench test carried out in workshop, were designed and presented. Finally, offshore tests were carried out and the power performance of the rotor was obtained and compared with the published literatures, and the results showed that the power coefficient was satisfactory, which agrees with the theoretical predictions. 相似文献
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The paper presents the effects of blade twist and nacelle shape on the performance of horizontal axis tidal current turbines using both analytical and numerical methods. Firstly, in the hydrodynamic design procedure, the optimal profiles of untwisted and twisted blades and their predicted theoretical turbine performance are obtained using the genetic algorithm method. Although both blade profiles produce desired rated rotational speed, the twisted blade achieves higher power and thrust performance. Secondly, numerical simulation is performed using sliding mesh technique to mimic rotating turbine in ANSYS FLUENT to validate the analytical results. The Reynolds-Averaged Navier-Stokes (RANS) approximation of the turbulence parameters is applied to obtain the flow field around the turbine. It is found that power and axial thrust force from BEMT (Blade Element Momentum Theory) method are under-predicted by 2% and 8% respectively, compared with numerical results. Afterwards, the downstream wake field of the turbine is investigated with two different nacelle shapes. It is found that the rotor performance is not significantly affected by the different nacelle shapes. However, the structural turbulence caused by the conventional nacelle is stronger than that by the NACA-profiled shape, and the former can cause detrimental effect on the performance of the downstream turbines in tidal farms. 相似文献
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In recent times, self-rectifying axial-flow air turbines are being widely employed in oscillating water column (OWC) wave energy converters (WEC). The steady performance of air turbines has been systematically investigated in previous studies. However, there still exists a lack of information on their unsteady performance, such as in the self-starting characteristics and subsequent running behavior. In this study, the unsteady behavior of impulse turbine under various constant-flow conditions is investigated. Experimental studies were conducted to investigate the effects of constant-load on the variations in the rotation speed, the pressure drop and the torque output of the turbine starting from rest. A fully passive flow-driving numerical model is employed for further detailed analysis of the flow and pressure fields. Followed by a well-agreed validation using the corresponding experimental data, the three dimensional (3D) transient model is used to study the effects of the air-flow velocity magnitude and the rotors’ moment of inertia on the self-starting performance of the turbine. Except for the variations in the rotation speed, the pressure drop and the pneumatic torque, the distributions of the flow-field and the pressure over the blades at specific time-points are analyzed. 相似文献
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The purpose of the present study is to investigate the performance and three-dimensional flow fields in a water-jet pump. TASCflow is employed to simulate the rotator-stator coupling flow field. A standard k-ε turbulence model combined with standard wall functions is used. In order to investigate the effect of a rear stator on flow fields, the flows in two water-jet pumps with and without a rear stator are studied. Computational fluid dynamics (CFD)-predicted overall performances are in good agreement with the experimental results. Then the flow fields, such as the pressure distribution on the blade surfaces, and the axial and tangential velocity distribution, especially the radial loading distribution, are investigated at different flow rates. In addition, the effects of a rear stator and different spacings between the rotor and the stator on the overall performance and the flow fields of the water-jet pump are also investigated. 相似文献
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《中国海洋工程》2021,(3)
Three blade-geometry optimization models derived along with assumptions from the blade element momentum(BEM) approach are studied by using a steady BEM code to improve a small horizontal-axis rotor of three blades that has been previously used in experiments. The base rotor blade has linear-radially varying chord length and pitch angle, while the other three models noted as Burton, Implicit and Hansen due to their references and characteristics yield blades of non-linearly varying chord length and pitch angle. The aim is to compare these rapid models and study how assumptions embedded in them affect performance and induction factors. It is found that the model that has the least assumptions(Hansen) and which considers the blade-profile drag in its optimization procedure yields the highest power coefficient, C_P, at the optimal tip speed ratio(TSR), about 7% higher than the base one and also higher C_P at high TSR. It produces an axial induction factor distribution along the blade that is closest to the 1 D optimal value of 1/3. All optimized tangential induction-factor distributions along the blade closely vary as inverse to the square of the radial distance, while being mildly higher than the base distribution. It shows that sufficient swirl is necessary to increase power but at a level causing not too much energy loss in unnecessary swirl of the wake. At high TSR, all optimized rotors adversely produce higher thrust than the base one, but the one with most embedded assumptions(Burton) produces the highest thrust. Details of all three optimization models are given along with the distributions of the power, thrust, blade hydrodynamic efficiency and induction factors. 相似文献
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通过水轮机捕能是当前常用的海洋能利用方式之一。桨叶作为水轮机关键部件,其性能一直是研究的重点。针对目前波浪条件下带负载运转的Savonius型水轮机相关捕能性能研究较少的情况,采用数值仿真方法,结合对应工况条件的物理试验,研究了一种Savonius型水轮机在不同波浪环境下带负载运转的捕能性能。采用Star CCM+仿真软件,建立数值波浪水池,设置环境参数,划分网格调整变量进行水轮机运转的水动力模型数值研究。在造波试验水池中利用推板改变波浪周期与波高,进行水轮机运转的物理试验。采集在不同负载下水轮机桨叶的转速和扭矩数据,计算并分析功率等参数,总结变化趋势,评价捕能效果。研究发现水轮机在1.6 s的波浪周期条件下,桨叶承受1.5 N·m负载时达到最佳捕能效果,其功率为23 W。为实际海域中水轮机桨叶的结构设计研究和相关工程应用提供参考。 相似文献