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自转清洗扭带管对流传热强化机理的实验研究 被引量:17
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作者 张琳 俞秀民 +1 位作者 宣益民 彭德其 《热能动力工程》 CAS CSCD 北大核心 2003年第6期608-611,共4页
具有传热强化功能的自转螺旋扭带清洗防垢技术发展较快。应用激光测速仪LDV(LaserDopplerVelocimeter)实验研究自转清洗扭带管内流体的湍流特性。结果表明 :在自转扭带的带动下 ,管内流体的流动结构发生了反常态的变化 ,在近管壁环形区... 具有传热强化功能的自转螺旋扭带清洗防垢技术发展较快。应用激光测速仪LDV(LaserDopplerVelocimeter)实验研究自转清洗扭带管内流体的湍流特性。结果表明 :在自转扭带的带动下 ,管内流体的流动结构发生了反常态的变化 ,在近管壁环形区域内流体的轴向分速度明显比管中心区域的高 ,轴向湍流度比无自转扭带时大 ;切向分速度随半径的增大而增大 ,并且存在很大的径向湍流度。这些结果初步说明了自转螺旋扭带管对流传热强化的机理是 :管内由扭带带动形成的强制旋流和轴向平行流叠加而形成的螺旋流动 ,以及近管壁环形区域内流速的增大 ,不仅加强了边界层流体的扰动以及边界层流体与主流流体的混合 ,并且使边界层厚度减簿 ,从而才使管内的对流传热得以强化。本文试验研究的结果为自转螺旋扭带管内对流传热强化机理的深入理论研究提供实验基础。 展开更多
关键词 自转螺旋扭带 激光测速 LDV 湍流特性 对流传热强化机理 实验研究 自转清洗扭带管 换热器
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基于增强协同与减少耗散的对流传热强化理论研究 被引量:6
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作者 刘伟 肖辉 《中国科学:技术科学》 EI CSCD 北大核心 2021年第10期1166-1177,共12页
对流传热具有守恒、协同和耗散三大特性,揭示其内在联系与基本规律对发展对流传热强化理论意义重大.本文基于能量和动量传输的本构和守恒关系,全面审视对流传热的多场协同与不可逆耗散机制,分析流体传热、耗功及惯性协同角之间的相互关... 对流传热具有守恒、协同和耗散三大特性,揭示其内在联系与基本规律对发展对流传热强化理论意义重大.本文基于能量和动量传输的本构和守恒关系,全面审视对流传热的多场协同与不可逆耗散机制,分析流体传热、耗功及惯性协同角之间的相互关系,提出反映对流传热不可逆耗散的热效率和?效率,探索基于增强协同与减少耗散的对流传热强化理论.基于此,提出一种V型复合肋槽强化传热管并进行湍流换热计算模拟.研究发现:与光滑圆管相比,在管壁形成V型复合肋槽可减小强化管的传热和惯性平均协同角,热效率和?效率分别超过92%和34%,性能和效能评价系数分别为1.22~1.69和0.53~1.07. 展开更多
关键词 多场协同 不可逆耗散 对流传热强化 复合肋槽管
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场协同原理在强化换热与脉管制冷机性能改进中的应用(上) 被引量:13
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作者 陶文铨 何雅玲 《西安交通大学学报》 EI CAS CSCD 北大核心 2002年第11期1101-1105,共5页
简要地介绍了场协同原理的基本思想 ,综述了文献中应用数值分析方法讨论场协同原理在强化单相对流换热分析中的应用情况 ,说明场协同原理可以将现有文献中关于强化单相对流换热的 3种说法统一起来 ,因而是强化单相对流换热的统一理论 .
关键词 脉管制冷机 强化换热 场协同原理 数值模拟 传热 强化单相对流传热 性能改进
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矩形通道中涡流发生器换热性能的实验研究与模拟 被引量:4
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作者 刘春江 阮仁君 +3 位作者 郭凯 齐文哲 陶敏 黄哲庆 《天津大学学报(自然科学与工程技术版)》 EI CSCD 北大核心 2017年第1期71-76,共6页
通过换热实验和CFD模拟,在Re=150~1,200范围内对布置有斜截式半椭圆柱型涡流发生器的矩形换热通道内的流动和换热特性进行研究,并对其强化换热机理进行了分析.结果表明,布置有涡流发生器的换热通道较光滑通道Nu增加,压降增大,并且强化... 通过换热实验和CFD模拟,在Re=150~1,200范围内对布置有斜截式半椭圆柱型涡流发生器的矩形换热通道内的流动和换热特性进行研究,并对其强化换热机理进行了分析.结果表明,布置有涡流发生器的换热通道较光滑通道Nu增加,压降增大,并且强化效果随Re增大而增强.在涡流发生器布置处产生了纵向涡,使截面涡量值大幅增加,从而强化了换热过程. 展开更多
关键词 对流传热强化 涡流发生器 涡量值 流动特性 计算流体力学
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Passive heat transfer enhancement of laminar mixed convection flow in a vertical dimpled tube 被引量:3
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作者 M.TOOFANI SHAHRAKI A.LAVAJOO A.BEHZADMEHR 《Journal of Central South University》 SCIE EI CAS CSCD 2021年第11期3477-3490,共14页
Heat transfer enhancement in vertical tubes plays an important role on the thermal performance of many heat exchangers and thermal devices.In this work,laminar mixed convection of airflow in a vertical dimpled tube wa... Heat transfer enhancement in vertical tubes plays an important role on the thermal performance of many heat exchangers and thermal devices.In this work,laminar mixed convection of airflow in a vertical dimpled tube was numerically investigated.Three-dimensional elliptical governing equations were solved using the finite-volume technique.For a given dimpled pitch,the effects of three different dimple heights(h/D=0.013,0.027,0.037) have been studied at different Richardson numbers(0.1,1.0 and 1.5).The generated vortex in the vicinity of the dimple destructs the thermal boundary layer and enhances the heat transfer.Therefore,lower wall temperature is seen where the dimples are located.Fluid flow velocity at the near-wall region significantly increases because of buoyancy forces with the increase of Richardson numbers.Such an acceleration at the near-wall region makes the dimples more effective at higher Richardson number.Using a dimpled tube enhances the heat transfer coefficient.However,the pressure drop is not important.For instance,in the case of Ri=1.5 and h/D=0.037,20% gains in the heat transfer enhancement only costs2.5% in the pressure loss.In general,it is recommended using a dimpled tube where the effects of buoyancy forces are important. 展开更多
关键词 dimpled tube laminar mixed convection vertical tube heat transfer enhancement
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Convective Heat Transfer Enhancement of a Rectangular Flat Plate by an Impinging Jet in Cross Flow 被引量:2
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作者 李国能 郑友取 +1 位作者 胡桂林 张治国 《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2014年第5期489-495,共7页
Experiments were carried out to study the heat transfer performance of an impinging jet in a cross flow.Several parameters including the jet-to-cross-flow mass ratio(X=2%-8%), the Reynolds number(Red=1434-5735)and the... Experiments were carried out to study the heat transfer performance of an impinging jet in a cross flow.Several parameters including the jet-to-cross-flow mass ratio(X=2%-8%), the Reynolds number(Red=1434-5735)and the jet diameter(d=2-4 mm) were explored. The heat transfer enhancement factor was found to increase with the jet-to-cross-flow mass ratio and the Reynolds number, but decrease with the jet diameter when other parameters maintain fixed. The presence of a cross flow was observed to degrade the heat transfer performance in respect to the effect of impinging jet to the target surface only. In addition, an impinging jet was confirmed to be capable of enhancing the heat transfer process in considerable amplitude even though the jet was not designed to impinge on the target surface. 展开更多
关键词 impinging jet cross flow convection heat transfer heat transfer enhancement
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Convective mass transfer enhancement in a membrane channel by delta winglets and their comparison with rectangular winglets
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作者 闵敬春 张冰强 《Chinese Journal of Chemical Engineering》 SCIE EI CAS CSCD 2015年第11期1755-1762,共8页
Numerical calculations were conducted to simulate the flow and mass transfer in narrow membrane channels equipped with delta winglets, which are often used as longitudinal vortex generators to enhance heat transfer in... Numerical calculations were conducted to simulate the flow and mass transfer in narrow membrane channels equipped with delta winglets, which are often used as longitudinal vortex generators to enhance heat transfer in heat exchanger applications. The channel consists of an impermeable solid wall and a membrane. The delta winglets are attached to the solid wall surface to enhance the mass transfer near the membrane surface and suppress the concentration polarization. The winglet performance was evaluated in terms of concentration polarization factor versus consumed pumping power. Calculations were implemented for NaCl solution flow in a membrane channel having a height of 2.0 mm for Reynolds numbers ranging from 400 to 1000. The delta wing- lets were optimized under equal pumping power condition, and the results of optimization suggest winglet height of 5/6 of the channel height, aspect ratio of 2.0, attack angle of 30% and a winglet interval equal to the channel height The optimal delta winglets were compared with the optimal rectangular winglets we found previously, and it is shown that the rectangular winglets yield a somewhat better performance than the delta winglets. @ 2015 The Chemical Industry and Engineering Society of China, and Chemical Industry Press. All rights reserved. 展开更多
关键词 Membrane processConcentration polarizationMass transfer enhancementDelta wingletPumping power
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Evaluation of convective heat transfer in a tube based on local exergy destruction rate 被引量:3
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作者 WANG JunBo LIU ZhiChun LIU Wei 《Science China(Technological Sciences)》 SCIE EI CAS CSCD 2016年第10期1494-1506,共13页
In this study, exergy efficiency is defined to evaluate convective heat transfer in a tube based on the local exergy destruction rate from the equilibrium equation of available potential. By calculating this destructi... In this study, exergy efficiency is defined to evaluate convective heat transfer in a tube based on the local exergy destruction rate from the equilibrium equation of available potential. By calculating this destruction rate, the local irreversibility of convective heat transfer can be evaluated quantitatively. The exergy efficiency and distribution of local exergy destruction rate for a smooth tube, an enhanced tube into which short-width twisted tape has been inserted, and an optimized tube with exergy destruction minimization are analyzed by solving the governing equations through a finite volume method(FVM). For the smooth tube, the exergy efficiency increases with increasing Reynolds number(Re) and decreases as the heat flux increases, whereas the Nusselt number(Nu) remains constant. For the enhanced tube, the exergy efficiency increases with increasing Reynolds number and increases as the short-width rate(w) increases. An analysis of the distribution of the local exergy destruction rate for a smooth tube shows that exergy destruction in the annular region between the core flow and tube wall is the highest. Furthermore, the exergy destruction for the enhanced and optimized tubes is reduced compared with that of the smooth tube. When the Reynolds number varies from 500 to 1750, the exergy efficiencies for the smooth, enhanced, and optimized tubes are in the ranges 0.367–0.485, 0.705–0.857, and 0.885–0.906, respectively. The results show that exergy efficiency is an effective evaluation criterion for convective heat transfer and the distribution of the local exergy destruction rate reveals the distribution of local irreversible loss. Disturbance in the core flow can reduce exergy destruction, and improve the exergy efficiency as well as heat transfer rate. Besides, optimization with exergy destruction minimization can provide effective guidance to improve the technology of heat transfer enhancement. 展开更多
关键词 convective heat transfer available potential exergy destruction rate exergy efficiency
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