LLC-Tray与倒盆顶帽罩单罩液体提升量的研究
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摘要
本文利用空气—水系统,在600×800的矩形塔上测定立体连续传质塔板(LLC-Tray)的板上清液层高度以及液面梯度的变化规律,并对LLC-Tray和倒盆顶帽罩的单罩液体提升量进行了测量,建立了LLC-Tray单罩液体提升量数学模型。具体如下:
1、LLC-Tray板上清液层高度随液体流量的增加而增加,随堰高的增加而增大,气速对清液层高度的影响很小。
2、LLC-Tray液面梯度的主要影响因素是液体流量和堰高。液面梯度随液体流量的增加而增加,随堰高的增加而增大。
3、LLC-Tray的液体提升量随气速的增大而减小;随清液层高度的增大而增多。倒盆顶帽罩液体提升量随气速的增大而增大;随清液层高度的增大而增多;随底隙的增加而增加。本文还分析了液体提升量对新型垂直筛板塔塔板压降、漏液量、雾沫夹带量以及由漏液量、雾沫夹带量决定的气体操作上、下限的影响。
4、根据能量守恒定律对LLC-Tray单罩液体提升量建立了数学模型,并用本文的实验数据对该模型进行了验证,结果证明,该模型可以比较好的反映影响LLC-Tray单罩液体提升量的因素及变化规律。
The clear liquid height, gradient of liquid level and liquid lift-up of LLC-Tray and the cap of inverse basin tip were measured in the rectangle experiment column with the side of 600 ×800 and the mathematic model of liquid lift-up of LLC-Tray was established. The detailed results are as follows.
1.The clear liquid height of LLC-Tray increases with the increase of liquid flow and the height of weir but hardly varies with the gas speed.
2.The mainly influencing factors of gradient of liquid level of LLC-Tray are liquid flow and the height of weir. Gradient of liquid level increases with the increase of liquid flow and the height of weir.
3.The liquid lift-up of LLC-Tray decreases with the hole-air-speed and increases with the clear liquid height. The liquid lift-up of the cap of inverse basin tip increases with the hole-air-speed, the clear liquid height and the bottom gap. The effects of liquid lift-up on pressure drop, weeping quantity liquid entrainment and upper-lower limit of air speed are also analyzed.
4.On the basis of conversation of energy the mathematic model of liquid lift-up was established which can describe the experimental data.
1、LLC-Tray板上清液层高度随液体流量的增加而增加,随堰高的增加而增大,气速对清液层高度的影响很小。
2、LLC-Tray液面梯度的主要影响因素是液体流量和堰高。液面梯度随液体流量的增加而增加,随堰高的增加而增大。
3、LLC-Tray的液体提升量随气速的增大而减小;随清液层高度的增大而增多。倒盆顶帽罩液体提升量随气速的增大而增大;随清液层高度的增大而增多;随底隙的增加而增加。本文还分析了液体提升量对新型垂直筛板塔塔板压降、漏液量、雾沫夹带量以及由漏液量、雾沫夹带量决定的气体操作上、下限的影响。
4、根据能量守恒定律对LLC-Tray单罩液体提升量建立了数学模型,并用本文的实验数据对该模型进行了验证,结果证明,该模型可以比较好的反映影响LLC-Tray单罩液体提升量的因素及变化规律。
The clear liquid height, gradient of liquid level and liquid lift-up of LLC-Tray and the cap of inverse basin tip were measured in the rectangle experiment column with the side of 600 ×800 and the mathematic model of liquid lift-up of LLC-Tray was established. The detailed results are as follows.
1.The clear liquid height of LLC-Tray increases with the increase of liquid flow and the height of weir but hardly varies with the gas speed.
2.The mainly influencing factors of gradient of liquid level of LLC-Tray are liquid flow and the height of weir. Gradient of liquid level increases with the increase of liquid flow and the height of weir.
3.The liquid lift-up of LLC-Tray decreases with the hole-air-speed and increases with the clear liquid height. The liquid lift-up of the cap of inverse basin tip increases with the hole-air-speed, the clear liquid height and the bottom gap. The effects of liquid lift-up on pressure drop, weeping quantity liquid entrainment and upper-lower limit of air speed are also analyzed.
4.On the basis of conversation of energy the mathematic model of liquid lift-up was established which can describe the experimental data.
引文
[1] 唐川公一.气液接触装置[P].日本:特许公报,昭46-31 321,1971.
[2] 谷川彰吾,横山武,唐川公一.气液接触装置[P].日本:特许公报,昭49-45131,1974.
[3] 谷川彰吴,横山武,唐川公一.气液接触液分散型开发[J].别册化学工业(日),1980,24(10):82~85.
[4] 西田勇.气液接触装置液分散型开发[J].石油学会志(日),1975,18(8):649~654.
[5] Shogo T. Newly Developed Tray for Distillation and Its Applications[J]. Chem. Econ.& Eng. Rev., 1973, 5(2): 22~28.
[6] Shogo.T, Takesi.Y. Gas-liquid Contacting Apparatus [P].US:3864439,1975.
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[10] 杜佩衡.新型直筛孔塔盘(New-VST)浅介[J].河北化工,1983,(4):59-66.
[11] 徐维勤,沈自求.新型垂直筛板的流体力学性能研究[J].化学工程,1982,10(2):14-15.
[12] 刘衎烈,佛明义,徐佟建.关于新型垂直筛板的初步探讨—流体力学[J].化学工程,1982,10(2):16-24.
[13] 兰州石油机械研究所塔器组.关于新型垂直筛板(VST)的初步研究[J].化学工程,1982,10(2):25-34.
[14] 徐维勤,沈自求.新型垂直筛板的流体力学性能[J].化工学报,1983,(2):184-193.
[15] 兰州石油机械研究所塔器组.新型垂直筛板的流体力学研究[J].化工学报,1983,(1):1-7.
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[17] 徐维勤.新型垂直筛板的改进[J].化学工程,1984,12(6):12-17.
[18] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8.
[19] 卢淘元.浮舌塔板在减压蒸馏塔中的应用.石油化工设备.1991,20(2):56-57
[20] 计建炳,谭天恩.板式塔的进展.化工时刊.2000,14(1):19-27
[21] 陈宗松.T型条阀塔盘的研究.化学工程.1992,20(3):41-45
[22] 杜佩衡.我国板式塔技术发展及展望.河北工学院学报.1985,14(1):108-117
[23] 杜佩衡.新型垂直筛孔塔盘(New VST)浅析.河北化工.1983,(2):59-66
[24] 谢英奋,袁小平.条形浮阀塔盘在常压分馏塔上的应用.广石化科技信息.1992,4(2):86-92
[25] 陈文炳.新型的酒精蒸馏装置—角钢浮动塔盘.浙江化工.1990,22(4):36-38
[26] 路秀林,赵培.导向浮阀塔盘.化学工程.1992,20(3):41-45
[27] 沈复.船型浮阀(HTV)塔板.石油化工设备技术.1991,12(6):22-24
[28] 刘衎烈,佛明义.矩形喷射塔板初步研究[J].化学工程,1986,14(3):16-24.
[29] 李好管,温卫东.复合塔板的开发及其工业应用[J].煤化工,2000,(4):12-16.
[30] 刘继东.新型垂直筛板塔空间持液量的研究[D].天津:河北工业大学,1997.
[31] 赖文衡.关于垂直筛板压降问题[J].化学工程,1983,11(5):38-41.
[32] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8.
[33] 杜佩衡,刘金成.新型垂直筛板的研究与评述[J].石油化工设备,1988,17(1):27-31.
[34] Shogo. T, Takesi.Y. Gas-liquid Contacting Apparatus [P].US:3864439,1975.
[35] 曹立珊.New-VST罩顶空间气相中液滴粒度分布规律测定及某些流体力学性能关联[D].天津:河北工业大学,1988.
[36] 赖文衡.关于垂直筛板压降问题[J].化学工程,1983,11(5):38-41.
[37] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8
[38] 董艳河.喷射型立体连续传质塔板的结构及性能研究[D].天津:河北工业大学,2003.
[39] 王志英.立体传质塔板上液相流动性能的研究[D].天津:河北工业大学,2002.
[40] 崔宝林.新型垂直筛板塔(New-VST)性能研究[D].大津:河北工业大学,1990.
[41] 王树楹.塔器技术的发展现状与展望[J].现代化工.1997,(11):16-19
[42] G.B.Wallis, "One—Dimensional Two—Phase Flow", 1969
[43] D.Butterworth and G.F.Hewitt, "Two—Phase Flow", 1978
[44] 兰州石油机械研究所,《现代塔器技术》,1972
[45] 姚玉英,黄风廉,陈常贵.《化工原理(新版)》.天津:天津大学出版社,1999.334-335
[46] 黄洁,王忠诚.塔板持液量的测定与计算[J].化学工程,1993,2(4):6~10
[47] 尾野馨,寺本通朗.别册化学工业(日),11月号,72(1967)
[48] Ludiwg, E.E.: "Applied Process Design for Chemical and Petrochemical Plants" Vol. 2. Second Edition, Gulf Publishing company, Houston, Texas, (1979).
[2] 谷川彰吾,横山武,唐川公一.气液接触装置[P].日本:特许公报,昭49-45131,1974.
[3] 谷川彰吴,横山武,唐川公一.气液接触液分散型开发[J].别册化学工业(日),1980,24(10):82~85.
[4] 西田勇.气液接触装置液分散型开发[J].石油学会志(日),1975,18(8):649~654.
[5] Shogo T. Newly Developed Tray for Distillation and Its Applications[J]. Chem. Econ.& Eng. Rev., 1973, 5(2): 22~28.
[6] Shogo.T, Takesi.Y. Gas-liquid Contacting Apparatus [P].US:3864439,1975.
[7] Shogo.T, Takesi.Y. Gas-liquid Contacting Apparatus[P].US:3779527, 1973.
[8] Shogo,T, Takesi.Y. Gas-liquid Contacting Apparatus[P].US:3779528, 1973.
[9] Kouicki.K,Shogo.TGas-liquid Contacting Apparatus. [P].US:3633882,1972.
[10] 杜佩衡.新型直筛孔塔盘(New-VST)浅介[J].河北化工,1983,(4):59-66.
[11] 徐维勤,沈自求.新型垂直筛板的流体力学性能研究[J].化学工程,1982,10(2):14-15.
[12] 刘衎烈,佛明义,徐佟建.关于新型垂直筛板的初步探讨—流体力学[J].化学工程,1982,10(2):16-24.
[13] 兰州石油机械研究所塔器组.关于新型垂直筛板(VST)的初步研究[J].化学工程,1982,10(2):25-34.
[14] 徐维勤,沈自求.新型垂直筛板的流体力学性能[J].化工学报,1983,(2):184-193.
[15] 兰州石油机械研究所塔器组.新型垂直筛板的流体力学研究[J].化工学报,1983,(1):1-7.
[16] 刘衎烈,翁力,王昂,等.新型垂直筛板的流体力学理论分析及关联[J].化学工程,1983,11(5):1-13.
[17] 徐维勤.新型垂直筛板的改进[J].化学工程,1984,12(6):12-17.
[18] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8.
[19] 卢淘元.浮舌塔板在减压蒸馏塔中的应用.石油化工设备.1991,20(2):56-57
[20] 计建炳,谭天恩.板式塔的进展.化工时刊.2000,14(1):19-27
[21] 陈宗松.T型条阀塔盘的研究.化学工程.1992,20(3):41-45
[22] 杜佩衡.我国板式塔技术发展及展望.河北工学院学报.1985,14(1):108-117
[23] 杜佩衡.新型垂直筛孔塔盘(New VST)浅析.河北化工.1983,(2):59-66
[24] 谢英奋,袁小平.条形浮阀塔盘在常压分馏塔上的应用.广石化科技信息.1992,4(2):86-92
[25] 陈文炳.新型的酒精蒸馏装置—角钢浮动塔盘.浙江化工.1990,22(4):36-38
[26] 路秀林,赵培.导向浮阀塔盘.化学工程.1992,20(3):41-45
[27] 沈复.船型浮阀(HTV)塔板.石油化工设备技术.1991,12(6):22-24
[28] 刘衎烈,佛明义.矩形喷射塔板初步研究[J].化学工程,1986,14(3):16-24.
[29] 李好管,温卫东.复合塔板的开发及其工业应用[J].煤化工,2000,(4):12-16.
[30] 刘继东.新型垂直筛板塔空间持液量的研究[D].天津:河北工业大学,1997.
[31] 赖文衡.关于垂直筛板压降问题[J].化学工程,1983,11(5):38-41.
[32] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8.
[33] 杜佩衡,刘金成.新型垂直筛板的研究与评述[J].石油化工设备,1988,17(1):27-31.
[34] Shogo. T, Takesi.Y. Gas-liquid Contacting Apparatus [P].US:3864439,1975.
[35] 曹立珊.New-VST罩顶空间气相中液滴粒度分布规律测定及某些流体力学性能关联[D].天津:河北工业大学,1988.
[36] 赖文衡.关于垂直筛板压降问题[J].化学工程,1983,11(5):38-41.
[37] 杜佩衡,王庆瑶,于文奎.新型垂直筛板的流体力学性能研究[J].石油化工设备,1986,15(9):1-8
[38] 董艳河.喷射型立体连续传质塔板的结构及性能研究[D].天津:河北工业大学,2003.
[39] 王志英.立体传质塔板上液相流动性能的研究[D].天津:河北工业大学,2002.
[40] 崔宝林.新型垂直筛板塔(New-VST)性能研究[D].大津:河北工业大学,1990.
[41] 王树楹.塔器技术的发展现状与展望[J].现代化工.1997,(11):16-19
[42] G.B.Wallis, "One—Dimensional Two—Phase Flow", 1969
[43] D.Butterworth and G.F.Hewitt, "Two—Phase Flow", 1978
[44] 兰州石油机械研究所,《现代塔器技术》,1972
[45] 姚玉英,黄风廉,陈常贵.《化工原理(新版)》.天津:天津大学出版社,1999.334-335
[46] 黄洁,王忠诚.塔板持液量的测定与计算[J].化学工程,1993,2(4):6~10
[47] 尾野馨,寺本通朗.别册化学工业(日),11月号,72(1967)
[48] Ludiwg, E.E.: "Applied Process Design for Chemical and Petrochemical Plants" Vol. 2. Second Edition, Gulf Publishing company, Houston, Texas, (1979).