1) condensation heat
凝结热
1.
The thermodynamic law between the condensation heat and vaporization heat as well as between the reaction heat and vaporization heat is studied during low temperature oxidation of low rank using pulse calorimeter.
采用pulsecalorimeter仪器,分别研究了低温下低阶煤在湿的氮气气氛下凝结热与蒸发热间的热力学规律,以及在湿的氧气气氛下反应热与蒸发热间的热力学规律;还研究了低阶煤在干燥氧气下经三次低温氧化反应的热力学规律。
2) condensation heat transfer
凝结换热
1.
Experimental investigation on condensation heat transfer in horizontal microfin and smooth tube with refrigerant R22;
R22在水平微肋管和光管内凝结换热的实验研究
2.
Marangoni condensation heat transfer for binary mixture vapor at different vapor pressures;
不同蒸气压力下的Marangoni凝结换热特性
3.
Investigation of condensation heat transfer of horizontal titanium circular-grooved tube;
钛波槽管水平管外凝结换热的实验研究
3) condensation
[英][,kɔnden'seɪʃn] [美]['kɑndɛn'seʃən]
凝结换热
1.
Flow and condensation of vapor with high partial pressure non-condensable gas in a separate heat pipe;
含高分压不凝气体的蒸汽在分离式热管内凝结换热
2.
Heat transfer coefficient and pressure drop were measured during condensation of steamin a vertical copper tube with and without Twined Wire Coil Inserts (TWCI), respectively.
1前言大空隙率多孔体管内插物-绕花丝内插物,被认为是强化管内凝结换热的最有效途径之一[1]。
3.
An experimental study is reported on forced-convective condensation heat transfer of R134a inside a horizontal smooth tube, using a 13m long, 11mm inside diameter test tube.
但是关于R134a的传热性能的研究还不够充分,尤其是对凝结换热,一些现有的关联式还不能很有把握地推广应用于R134a,还必须进行大量的研究工作,以查明R134a的传热特性。
5) Condensation heat transfer
凝结传热
1.
Electrohydrodynamic enhancement of condensation heat transfer in a horizontal tube;
电流体力学强化水平管内凝结传热试验研究
2.
Condensation heat transfer models of refrigerant outside horizontal low-finned tubes were surveyed.
综述了水平低翅片管外凝结传热的基本模型,阐述了二氧化碳制冷剂的物性特点,讨论了表面张力与凝液滞留角及二氧化碳管外凝结换热系数的关系,分析了翅片密度、环形翅片管尺寸对翅片效率、滞留角、凝结换热系数以及传热增强比的影响,优化了外翅片管的齿高与齿距,并求得相应的强化传热增强比。
3.
The calculation of condensation heat transfer outside horizontal tubes in refrigerators using mixed refrigerants is discussed.
分析了混合工质制冷机中水平管外凝结传热的计算问题,对守恒方程进行了处理,得出了分析解。
6) condensation heating
凝结加热
1.
Long-term NCEP-NCAR reanalysis condensation heating data were used to investigate its geographic pattern in the northern Pacific,especially its longterm variation in the region of the Aleutian Low.
利用1948~2003年NCEP再分析凝结加热率资料,研究了北太平洋地区整层凝结加热的季节演变,着重研究了阿留申低压地区(30~50°N,160~210°E)凝结加热的长期变化,探讨了它对北太平洋年代际变率可能的反馈。
2.
A sensitive numerical simulation study is carried out to investigate the effects of condensation heating and surface fluxes on the development of a South China MCS that occurred during 23~24 May 1998.
通过有无凝结加热和地表通量影响的数值模拟对比研究,分析了非绝热过程对一次华南暴雨MCS发生发展过程的影响。
3.
Seeing that condensation heating is the main part of diabatic heating in the monsoon region,then related numerical experiments in the above three regions are made so as to discuss the possible impacting approaches of condensation heating on general circulation.
所有数值试验都揭示了凝结加热可以首先在对流层中低层的加热区附近激发气旋性异常,然后异常向东北传播,并最终在中高纬地区形成正负中心相间的波列状结构,这在一定程度上体现了潜热加热能的向东向极频散过程。
补充资料:凝结热
见汽化热。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条