某冷水機組立式氣液分離器的設計與優(yōu)化
發(fā)布時間:2018-08-01 10:13
【摘要】:氣液分離器作為保障制冷系統(tǒng)安全運行的重要部件,廣泛應用于制冷系統(tǒng)中。由于運行工況的不同,氣液分離器尺寸結構的差異,其對制冷系統(tǒng)的整體運行將產生不同的影響。因此,對氣液分離器進行優(yōu)化設計有著重要的實際應用價值。本文以某型號的冷水機組的氣液分離器為研究對象,對其結構、流動和噪聲等展開了相應的分析和研究。(1)通過相關文獻和額定工況運行參數(shù)以及制冷劑充注量,確定了氣液分離器的容積、直徑及高度等參數(shù)數(shù)值。(2)在額定運行工況下,分別采用數(shù)值法和解析法,對氣液分離器進行了結構應力分析,得到封頭受力情況,結果顯示數(shù)值法更適合于額定工況下氣液分離器的受力計算。(3)對氣液分離器內制冷劑的流動進行數(shù)值模擬,得到氣液分離器內部壓力分布、速度分布及頻率聲壓關系曲線。結果顯示回油孔設置具有一定的合理性;氣動噪聲產生的位置主要位于氣液分離器的底部。(4)應用有限元方法對氣液分離器的殼體進行了模態(tài)分析,得到了分離器的固有頻率。對氣液分離器在壓縮機工作情況下進行了動態(tài)響應模擬,得到了動態(tài)響應曲線。(5)采用正交試驗設計方法,對氣液分離器內腔外套管長度、套管管徑比及回油孔孔徑對壓降的影響進行了研究。結果顯示,外套管高度為450mm,管徑比2.73時,對壓降的影響最大。
[Abstract]:As an important component to ensure the safe operation of refrigeration system, gas-liquid separator is widely used in refrigeration system. Because of the different operating conditions and the difference of the size and structure of the gas-liquid separator, it will have different influence on the whole operation of the refrigeration system. Therefore, the optimization design of gas-liquid separator has important practical application value. In this paper, the structure, flow and noise of the gas-liquid separator of a certain type of chillers are analyzed and studied. (1) through the relevant literature, operating parameters under rated operating conditions and refrigerant charge, The volume, diameter and height of the gas-liquid separator are determined. (2) under rated operating conditions, the structural stress of the gas-liquid separator is analyzed by numerical method and analytical method, and the stress of the head is obtained. The results show that the numerical method is more suitable for the force calculation of the gas-liquid separator under rated working conditions. (3) numerical simulation of the refrigerant flow in the gas-liquid separator is carried out, and the pressure distribution, velocity distribution and the relationship between frequency and sound pressure in the gas-liquid separator are obtained. The results show that the setting of the return hole is reasonable and the position of the pneumatic noise is mainly at the bottom of the gas-liquid separator. (4) the modal analysis of the shell of the gas-liquid separator is carried out by using the finite element method, and the natural frequency of the separator is obtained. The dynamic response of the gas-liquid separator is simulated under the condition of compressor operation, and the dynamic response curve is obtained. (5) the length of the casing tube in the inner cavity of the gas-liquid separator is calculated by the orthogonal design method. The influence of casing diameter ratio and oil return hole diameter on pressure drop is studied. The results show that the pressure drop is most affected when the tube height is 450 mm and the diameter ratio is 2.73.
【學位授予單位】:安徽工業(yè)大學
【學位級別】:碩士
【學位授予年份】:2017
【分類號】:TB657
[Abstract]:As an important component to ensure the safe operation of refrigeration system, gas-liquid separator is widely used in refrigeration system. Because of the different operating conditions and the difference of the size and structure of the gas-liquid separator, it will have different influence on the whole operation of the refrigeration system. Therefore, the optimization design of gas-liquid separator has important practical application value. In this paper, the structure, flow and noise of the gas-liquid separator of a certain type of chillers are analyzed and studied. (1) through the relevant literature, operating parameters under rated operating conditions and refrigerant charge, The volume, diameter and height of the gas-liquid separator are determined. (2) under rated operating conditions, the structural stress of the gas-liquid separator is analyzed by numerical method and analytical method, and the stress of the head is obtained. The results show that the numerical method is more suitable for the force calculation of the gas-liquid separator under rated working conditions. (3) numerical simulation of the refrigerant flow in the gas-liquid separator is carried out, and the pressure distribution, velocity distribution and the relationship between frequency and sound pressure in the gas-liquid separator are obtained. The results show that the setting of the return hole is reasonable and the position of the pneumatic noise is mainly at the bottom of the gas-liquid separator. (4) the modal analysis of the shell of the gas-liquid separator is carried out by using the finite element method, and the natural frequency of the separator is obtained. The dynamic response of the gas-liquid separator is simulated under the condition of compressor operation, and the dynamic response curve is obtained. (5) the length of the casing tube in the inner cavity of the gas-liquid separator is calculated by the orthogonal design method. The influence of casing diameter ratio and oil return hole diameter on pressure drop is studied. The results show that the pressure drop is most affected when the tube height is 450 mm and the diameter ratio is 2.73.
【學位授予單位】:安徽工業(yè)大學
【學位級別】:碩士
【學位授予年份】:2017
【分類號】:TB657
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