Experimental study on flash and mixing evaporation of aqueous NaCl solution

doi:10.11949/0438-1157.20230721

Abstract

Abstract:

Flash and mixing evaporation (FME) was one of the effective methods to achieve complete desalination of saline wastewater. In this paper, an experimental system of flash and cross-flow mixing evaporation was built, and the motion and evaporation characteristics of droplets in FME were investigated by combining PIV and Malvern laser particle size analyzer. In the experiment, on the wind side, air temperature ranged from 104.7℃ to 145.3℃, air speed from 10 m∙s^-1 to 17 m∙s^-1. On liquid side, the initial mass fraction of aqueous NaCl solution ranged from 0 to 0.15, its temperature from 20.0℃ to 132.0℃, and spray pressure ranged from 0.5 MPa to 1.2 MPa. Flash evaporation in FME mainly affected the atomization and fragmentation zone, while mixing evaporation mainly affected the evaporation zone. The initial particle size of droplets tended to be uniform with the increase of spraying pressure or mass fraction. While with the increase of droplet temperature, it tended to be uniform first and then became worse. The momentum/energy exchange between air and liquid mainly occurred in the horizontal direction in the evaporation zone. The average velocity of droplet cross-section along the horizontal direction was defined as the characteristic velocity of FME. This characteristic velocity first increases sharply and then increases slowly as the mixing distance increases. While at the same mixing distance, the characteristic velocity increased with the increase of mixing air temperature, air speed or spraying pressure. The Sauter diameter of droplets decreased along the mixing direction. The results pointed out that increasing the mixing air temperature, mixing air velocity or spray pressure was an effective means to enhance the FME process. The average surface heat transfer coefficient of the droplet population was calculated based on the experimental results and the experimental correlation equation for this heat transfer coefficient was set up and its relative error between the calculated and experimental values fell mainly in ±20%.

Key words: spray flash, evaporation, hydrodynamics, particle size distribution, average surface heat transfer coefficient, multiphase flow

摘要：

喷射闪蒸与热空气掺混蒸发（FME）结合是实现含盐废水深度脱盐的有效方法之一。本文搭建了喷射闪蒸-横流掺混蒸发实验系统，结合PIV和Malvern激光粒度仪对FME流场中液滴群的运动、蒸发特性开展了实验研究。实验中掺混风温为104.7~145.3℃、风速为10~17 m∙s^-1；液侧液滴初始盐质量分数为0~0.15，温度为20.0~132.0℃，喷射压力为0.5~1.2 MPa。FME中喷射闪蒸主要影响雾化破碎区，而掺混蒸发主要影响蒸发区。液滴群初始粒径随喷射压力或质量分数的提高趋于均匀，而随液滴温度的升高先趋于均匀而后均匀性变差。气液间的动量和能量交换主要发生在蒸发区内的水平方向；定义液滴沿水平方向截面平均速度为FME特征速度，该特征速度随掺混距离的增大先陡增后缓增，而在相同掺混距离处，该特征速度随掺混风温、风速或喷射压力的增大而增大；液滴群的Sauter平均直径沿掺混方向不断减小；增加掺混风温、提高掺混风速、增大喷射压力是强化FME蒸发的有效手段。根据实验结果计算了液滴群表面平均传热系数，并给出了该传热系数的实验关联式。在本文研究范围内，其计算值与实验值的主体误差在±20%之内。

关键词: 喷射闪蒸, 蒸发, 流体动力学, 粒径分布, 表面平均传热系数, 多相流

CLC Number:

TK 124

Yue YANG, Dan ZHANG, Jugan ZHENG, Maoping TU, Qingzhong YANG. Experimental study on flash and mixing evaporation of aqueous NaCl solution[J]. CIESC Journal, 2023, 74(8): 3279-3291.

杨越, 张丹, 郑巨淦, 涂茂萍, 杨庆忠. NaCl水溶液喷射闪蒸-掺混蒸发的实验研究[J]. 化工学报, 2023, 74(8): 3279-3291.

Figures/Tables 17

Fig.1 Flash and mixing evaporation (FME)

Fig.2 Experimental system of FME

Table 1 Main experimental parameters and range of test equipment

测量设备	型号	参数范围	精度	测量对象
PIV系统	LA ISION Nano PIV	0~2000 m·s^-1	—	雾羽速度场
Malvern激光粒度仪	Spraytecv3·20	0.1~2000 µm	0.02%	雾羽粒径分布
精密比重计	CJBMJ-24	0.650~1.850 kg·m^-3	5×10^-4 kg·m^-3	NaCl水溶液浓度
热电偶	T型铠装	-200~400℃	0.5℃	溶液温度和风温
压力表	Y-100	0~2.5 MPa	0.02MPa	水侧压力
空气流量计	BLLUGB-100	0~4000 m³·h^-1	±1%FS	风侧流量

Fig.3 Measuring position for particle size of plumes

Table 2 Uncertainty analyses of experimental parameters

实验参数	实验范围	绝对不确定度	最小测量值	最大相对不确定度
水侧压力p_w/MPa	0.5~1.2	0.03	0.50	0.006
液滴温度t_w/℃	20.0~132.0	0.5	20.00	0.048
掺混风温t_a /℃	104.7~145.3	0.2	104.70	0.061
初始盐质量分数f_m,0	0~0.15	5×10^-3	0.05	0.01
过热度ΔT/K	0~32.00	—	—	0.036
掺混距离Δx/mm	0~180.00	5×10^-4	0.03	0.017
掺混风速v_a /(m·s^-1)	10~17	0.031	10.00	2×10^-3
液滴速度u_d/(m·s^-1)	12.1~43.3	0.01	12.1	2.5×10^-3
液滴粒径d₃₂/μm	43.92~135.20	0.02	43.92	0.087

Fig.4 Repeatability validation of droplet size distribution and velocity field measurement

Fig.5 Typical morphology of plume of FME

Fig.6 Morphology of plume under different conditions

Fig.7 The variation of particle size distribution under different conditions

Fig.8 Velocity field distribution under different mixing air temperatures

Fig.9 Horizontal velocity of droplet

Fig.10 Velocity field distribution under different mixing air speeds

Fig.11 Velocity field distribution under different spray pressures

Fig.12 Variation of particle size and d32 along mixing distance under different air temperatures

Fig.13 Variation of d32 along mixing distance

Fig.14 Variation of average heat transfer coefficient under different conditions

Fig.15 Relative error between experimental and calculated Nu

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