共查询到19条相似文献,搜索用时 46 毫秒
1.
2.
提出在喷射器喷嘴内插入喷针来调节喷射器工作参数的方案,建立了可调武喷射器性能计算模型,分析了喷嘴截面积变化对喷射系数、气体压力、气体流量等参数的影响。结果表明,通过对喷射器喉口面积的调节,可以实现把出口流量控制在一个稳定的区域内,从而减小喷射器入口参数对出口参数以至整个系统的影响。可调式喷嘴可拓宽喷射器的有效工作范围。 相似文献
3.
4.
5.
6.
蒸汽喷射式热泵变工况性能分析 总被引:4,自引:1,他引:4
采用数值模拟的方法对低压蒸汽增压利用系统中的蒸汽喷射式热泵在非设计工况下的操作性能进行研究,计算并分析了工作蒸汽压力和温度、引射流体压力及混合流体压力等热力参数对热泵操作性能的影响。数值结果表明:当混合流体的压力低于一定的数值时,喷射系数维持一定值;而热泵对引射流体压力的变化极为敏感,引射压力的微小变化可能导致热泵操作性能的急剧下降;提高工作蒸汽的压力并不一定能改善喷射泵的工作性能,这是因为提高工作蒸汽压力会增加额外的蒸汽量所致;喷射系数随工作蒸汽温度的升高而略有增大,并近似呈线性率。 相似文献
7.
8.
9.
依据索科洛夫等学者提出的经验公式对喷射器进行优化设计,搭建了用于测量喷射器性能的实验台,以CO2为工质,分别研究当工作流体压力在8.0~9.6MPa、引射流体压力在2.4~2.8MPa以及工作流体温度在70~90℃时,喷嘴临界截面直径对喷射系数的变化规律。实验结果表明:当喷射器背压为3.9MPa、工作流体温度为90℃、引射流体压力为2.4MPa、工作流体压力在8.0~9.6MPa时,喷射器的喷射系数随喷嘴临界截面直径的增大而减小;当喷射器背压为3.9MPa、工作流体温度为90℃、工作流体压力为10.0MPa、引射流体压力在2.4~2.8MPa时,喷射器的喷射系数也随喷嘴临界截面直径的增大而减小;且喷射系数理论值与实验值吻合度较好,误差在±3.75%范围内。当喷射器工作流体压力为10.0MPa、引射流体压力为2.7MPa、喷射器背压为3.9MPa、工作流体温度在70~90℃时,喷射系数随着喷嘴临界截面直径的增大而逐渐减小。另外,在保持喷射器的基本工作参数不变时,工作流体压力及引射流体压力的提高对喷射器喷射系数均有提升作用。 相似文献
10.
11.
介绍了密闭式蒸汽凝结水回收节能技术,及采用抽汽喷射器的新技术来回收乏汽。分析了此类喷射器的工作特点和节能意义,介绍了此类喷射器在实际中的使用情况。 相似文献
12.
Xilai Zhang Shiping Jin Suyi Huang Guoqing Tian 《Frontiers of Energy and Power Engineering in China》2009,3(2):167-174
The influence of nozzle position on the performance of an ejector was analyzed qualitatively with free jet flow model. Experimental
investigations and computational fluid dynamics (CFD) analysis of the nozzle position of the subsonic ejector were also conducted.
The results show that there is an optimum nozzle position for the ejector. The ejecting coefficient reaches its maximum when
the nozzle is positioned at the optimum and decreases when deviating. Moreover, the nozzle position of an ejector is not a
fixed value, but is influenced greatly by the flow parameters. Considering the complexity of the ejector, CFD is reckoned
as a useful tool in the design of ejectors. 相似文献
13.
The paper presents the experimental results of a novel ejector refrigerator that was designed to be suitable for an air‐conditioning application using vacuum tube solar collectors for vapour generation. The primary flow of the ejector is controlled using a spindle in order to provide fine tuning for ejector operation as heat input changes with solar radiation. Water, the most environmentally friendly substance is used as the working fluid. The performance of the ejector was tested for a range of controlled primary flows, boiler temperatures, condensation capacities using different primary nozzles with different lengths. The effect of the operating conditions and nozzle length on the performance of the ejector was analyzed. It was found that in the tested boiler temperature range of 84–96°C the maximum cooling capacity (4.01 kW) of the ejector with short nozzle is much higher than that of the ejector with long nozzle (2.9 kW) on the spindle position of 21 mm. However, the ejector with long nozzle has increased COP when the boiler temperature is below 88°C and has higher critical back pressure. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
14.
建立了蒸汽喷射器热力学模型,并验证了该模型性能及结构计算的可靠性。并针对实际情况中,对该模型进行了动态模拟。结果显示:当工作流体的温度升高时,工质流体的质量流量都会增加,引射系数存在峰值,峰值所对应温度为热力学模型设定温度值;当引射流体的温度升高时,其质量流量也会随之增大,而工作流体的质量流量则较稳定,因此引射流体温度与压力的升高可以改善喷射器的性能;当背压升高时,在一定压力范围内,工质流体的质量流量都趋于稳定,而当背压超过热力学模型设定背压值时,引射流体的质量流量便随背压的升高而急剧下降,喷射器性能严重恶化,故认为该压力值为喷射器的临界背压。本文研究结果对喷射器的设计计算具有一定的指导作用。
关键词:蒸汽喷射器;热力学模型;数值模拟;引射系数 相似文献
15.
16.
17.
蒸汽喷射器流动参数与性能的数值分析 总被引:9,自引:0,他引:9
通过二维流动数值计算,分析了以水蒸气为工质的喷射器内工作流体压力、引射流体压力及出口压力对喷射系数的影响;探讨了各工作参数变化对喷射系数产生影响的原因,以及激波产生的条件、激波的位置、强度,产生引射流体雍塞的条件等。结果表明:喷射器存在临界的出口压力pd,当喷射器出口压力大于pd时,喷射器的喷射系数随出口压力升高而降低;当喷射器出口压力小于pd时,喷射器的喷射系数将保持不变。在计算模拟的制冷工况范围内,工作流体压力升高,引起喷射系数降低,pd升高;而引射流体压力升高时,喷射系数与pd都升高。 相似文献
18.
19.
Ejector refrigeration systems can use low grade thermal energy, at temperatures as low as 60°C, to provide space cooling. Since this waste energy is widely available and the cost of its supply is negligible in many cases, cooling costs can be lower than conventional systems, which makes the method very attractive. The present study describes a computer simulation model for ejector refrigeration systems that was developed using an existing ejector theory. This model allows for internal irreversibilities within the ejector to be included and caters for the addition of a regenerator and a precooler for improving the system coefficient of performance. The study shows that HCFC-123 is a suitable replacement for CFC-11 in this application. Results also indicate that the use of a variable geometry ejector can maintain the optimum performance of refrigeration systems when operating conditions change. 相似文献