多蒸发器热虹吸回路热管启动与不稳定性研究
发布时间:2021-11-18 15:52
多蒸发器热虹吸回路热管能够将自然冷能利用和低损耗冷量输配集成一体,在数据中心节能冷却领域具有独特的应用前景。本文建立了具有三蒸发器且流动可视化的热虹吸回路热管实验台,对其启动特性和运行不稳定性开展了研究,为其实际应用提供基础理论支撑。结果表明,启动过程中,在高充液率情况下沸腾倾向于率先发生在蒸发器顶部,达到稳态后,蒸发器顶部的温度更低,这是由于在蒸发器顶部气泡更大,沸腾更为剧烈。而在较小充液率下,蒸发器顶部和底部几乎同时发生沸腾,达到稳态后,顶部温度更高,这是由于充液率较小时液池在顶部发生蒸干;距离冷凝器较远的蒸发器由于连接管的流动阻力更大,启动峰值温度和稳态温度更高;对于某一蒸发器而言,加热与它并联的蒸发器后,与仅有单一蒸发器输入热量相比,温度波动的幅度有所增大而波动频率有所减小。
【文章来源】:工程热物理学报. 2020,41(04)北大核心EICSCD
【文章页数】:5 页
【部分图文】:
图4蒸发器内流型(仅蒸发器B输入36W,充液率27.0%)??⑷加热前;(b)沸腾产生瞬间;(c)稳态??Fig.?4?Flow?regime?inside?the?evaporator?(only?Evaporator?B??has?36?W?heating?power?and?filling?ratio?is?27%)?(a)?Before??heating;?(b)?The?moment?when?boiling?occurs?(c)?Steady??
/S??图9温度波动曲线(仅蒸发器B输入90?W,充液率79%)??Fig.?9?Temperature?fluctuation?(only?Evaporator?B?has?90?W??heating?power?and?filling?ratio?is?79%)??当蒸发器B、C均具有90?W输入热量、充液??率79%时,蒸发器B、C的温度波动如图10所示。??温度波动的幅度与单一蒸发器输入热量相比有所增??24??30??〇qL?B2??B3??(a)?(b)??图8蒸发器内流型(蒸发器A、B输入36?W,充液率41%)??(a)蒸发器A稳态;(b)蒸发器B稳态??Fig.?8?Flow?regime?inside?the?evaporator?(Evaporator?A?and??B?both?have?36?W?heating?power?and?filling?ratio?is?41%)??(a)?Steady?state?of?Evaporator?A;?(b)?Steady?state?of??Evaporator?B??2.2不稳定性??作为依靠重力循环的自然循环回路,热虹吸回??路热管具有一定的不稳定性。在某些工况下,热虹??吸回路最终的工作状态并不是所有参数始终保持恒??时间/s??M?1〇温度波#曲线辑发縣均输入SO?W,充液率79%)??Fig.?10?Temperature?fluctuation?(Evaporator?B?and?C?both??have?90?W?heating?power?and?filling?ratio?is?79%)??35.5??34.0??
张海南等:多蒸发器热虹吸回路热管启动与不稳定性研究??795??定,而是具有一定的波动。实验中在较高的充液率??下观察到了温度波动。当仅有蒸发器B具有90?W??输入热量、充液率79%时,蒸发器B的温度波动如??图9所示。温度波动的幅度较小,频率为0.215?Hz。??30.0??24_??时间/s??图7启动温度曲线(蒸发器A、B均输入36?W,充液率41%)??Fig.?7?Startup?temperature?curves?(Evaporator?A?and?B?both??have?36?W?heating?power?and?filling?ratio?is?41%)??4期??尺寸较小.这足由于蒸发器A距离冷凝器距离更远,??使得上升管和下降管内的流阻更大。??78?s??0?20?40?60?80?100??时间/S??图9温度波动曲线(仅蒸发器B输入90?W,充液率79%)??Fig.?9?Temperature?fluctuation?(only?Evaporator?B?has?90?W??heating?power?and?filling?ratio?is?79%)??当蒸发器B、C均具有90?W输入热量、充液??率79%时,蒸发器B、C的温度波动如图10所示。??温度波动的幅度与单一蒸发器输入热量相比有所增??24??30??〇qL?B2??B3??(a)?(b)??图8蒸发器内流型(蒸发器A、B输入36?W,充液率41%)??(a)蒸发器A稳态;(b)蒸发器B稳态??Fig.?8?Flow?regime?inside?the?evaporator?(Evapo
本文编号:3503179
【文章来源】:工程热物理学报. 2020,41(04)北大核心EICSCD
【文章页数】:5 页
【部分图文】:
图4蒸发器内流型(仅蒸发器B输入36W,充液率27.0%)??⑷加热前;(b)沸腾产生瞬间;(c)稳态??Fig.?4?Flow?regime?inside?the?evaporator?(only?Evaporator?B??has?36?W?heating?power?and?filling?ratio?is?27%)?(a)?Before??heating;?(b)?The?moment?when?boiling?occurs?(c)?Steady??
/S??图9温度波动曲线(仅蒸发器B输入90?W,充液率79%)??Fig.?9?Temperature?fluctuation?(only?Evaporator?B?has?90?W??heating?power?and?filling?ratio?is?79%)??当蒸发器B、C均具有90?W输入热量、充液??率79%时,蒸发器B、C的温度波动如图10所示。??温度波动的幅度与单一蒸发器输入热量相比有所增??24??30??〇qL?B2??B3??(a)?(b)??图8蒸发器内流型(蒸发器A、B输入36?W,充液率41%)??(a)蒸发器A稳态;(b)蒸发器B稳态??Fig.?8?Flow?regime?inside?the?evaporator?(Evaporator?A?and??B?both?have?36?W?heating?power?and?filling?ratio?is?41%)??(a)?Steady?state?of?Evaporator?A;?(b)?Steady?state?of??Evaporator?B??2.2不稳定性??作为依靠重力循环的自然循环回路,热虹吸回??路热管具有一定的不稳定性。在某些工况下,热虹??吸回路最终的工作状态并不是所有参数始终保持恒??时间/s??M?1〇温度波#曲线辑发縣均输入SO?W,充液率79%)??Fig.?10?Temperature?fluctuation?(Evaporator?B?and?C?both??have?90?W?heating?power?and?filling?ratio?is?79%)??35.5??34.0??
张海南等:多蒸发器热虹吸回路热管启动与不稳定性研究??795??定,而是具有一定的波动。实验中在较高的充液率??下观察到了温度波动。当仅有蒸发器B具有90?W??输入热量、充液率79%时,蒸发器B的温度波动如??图9所示。温度波动的幅度较小,频率为0.215?Hz。??30.0??24_??时间/s??图7启动温度曲线(蒸发器A、B均输入36?W,充液率41%)??Fig.?7?Startup?temperature?curves?(Evaporator?A?and?B?both??have?36?W?heating?power?and?filling?ratio?is?41%)??4期??尺寸较小.这足由于蒸发器A距离冷凝器距离更远,??使得上升管和下降管内的流阻更大。??78?s??0?20?40?60?80?100??时间/S??图9温度波动曲线(仅蒸发器B输入90?W,充液率79%)??Fig.?9?Temperature?fluctuation?(only?Evaporator?B?has?90?W??heating?power?and?filling?ratio?is?79%)??当蒸发器B、C均具有90?W输入热量、充液??率79%时,蒸发器B、C的温度波动如图10所示。??温度波动的幅度与单一蒸发器输入热量相比有所增??24??30??〇qL?B2??B3??(a)?(b)??图8蒸发器内流型(蒸发器A、B输入36?W,充液率41%)??(a)蒸发器A稳态;(b)蒸发器B稳态??Fig.?8?Flow?regime?inside?the?evaporator?(Evapo
本文编号:3503179
本文链接:https://www.wllwen.com/kejilunwen/dongligc/3503179.html
