李响,徐增辉,姜秀光,汪瞳,李前正,李金择,夏谢天,陈星.无气离心喷涂涂料液滴流场和分布特性的数值模拟[J].表面技术,2024,53(12):158-166.
LI Xiang,XU Zenghui,JIANG Xiuguang,WANG Tong,LI Qianzheng,LI Jinze,XIA Xietian,CHEN Xing.Numerical Simulations of Paint Droplet Hydrodynamics and Distributions in an Airless Spray Coating Process[J].Surface Technology,2024,53(12):158-166 |
| 无气离心喷涂涂料液滴流场和分布特性的数值模拟 |
| Numerical Simulations of Paint Droplet Hydrodynamics and Distributions in an Airless Spray Coating Process |
| 投稿时间:2023-07-11 修订日期:2023-11-18 |
| DOI:10.16490/j.cnki.issn.1001-3660.2024.12.013 |
| 中文关键词: 涂料液滴 无气离心喷涂 离散元方法 出流速度 液滴数分布 |
| 英文关键词:paint droplets airless spray coating discrete element method discharge velocity paint droplet number |
| 基金项目:中建二局科技资助计划(2021ZX180001);南京市玄武区企业专家工作室资助项目 |
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| Author | Institution |
| LI Xiang | China Construction Power and Environment Engineering Co., Ltd., Nanjing 210012, China;China Construction Eco-environmental Protection Technology Co., Ltd., Jiangsu Suzhou 215124, China |
| XU Zenghui | China Construction Eco-environmental Protection Technology Co., Ltd., Jiangsu Suzhou 215124, China |
| JIANG Xiuguang | China Construction Second Engineering Bureau Ltd., Beijing 100070, China |
| WANG Tong | China Construction Eco-environmental Protection Technology Co., Ltd., Jiangsu Suzhou 215124, China |
| LI Qianzheng | China Construction Power and Environment Engineering Co., Ltd., Nanjing 210012, China |
| LI Jinze | China Construction Power and Environment Engineering Co., Ltd., Nanjing 210012, China |
| XIA Xietian | China Construction Power and Environment Engineering Co., Ltd., Nanjing 210012, China |
| CHEN Xing | China Construction Eco-environmental Protection Technology Co., Ltd., Jiangsu Suzhou 215124, China |
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| 中文摘要: |
| 目的 探究无气体输送的无气离心喷涂法过程中涂料液滴与管道内壁面之间的相互碰撞接触作用,以在高分子涂料离心喷涂法中获得致密高强度涂料内衬层。方法 将涂料液滴视为离散相,利用离散元方法和涂料液滴附着力JKR接触模型,模拟无气离心喷涂涂料液滴运动特性。通过堆积角虚拟试验确定涂料液滴与壁面表面能。基于离心场作用下涂料液滴运动方程,导出旋转喷枪射流小孔出流速度计算模型。数值模拟无气离心喷涂过程涂料液滴流体动力特性,揭示涂料液滴碰撞作用下动态喷涂成膜规律。结果 统计得到涂料液滴在水平壁面展平的表面能为32.7 J/m2。对于一定的喷嘴射流小孔,涂料液滴小孔出流系数接近于常数。随着计算时间的推进,壁面黏附涂料液滴数不断增加。在无气旋转喷枪II旋转速度2 500 r/min下,统计单元涂料液滴数最大,并且有较大的液滴数方差和相对误差。随着喷枪旋转速度的提高,涂料液滴数的方差和相对误差降低。结论 为实现沿管道壁面涂料液滴均匀分布,旋转喷枪II旋转速度建议不应低于5 000 r/min。 |
| 英文摘要: |
| It is an advanced surface modification technology using paint droplet rotary spray coating in pipelines trenchless rehabilitation, which can improve surface anticorrosion properties. Due to the difference of collisional contact interactions of paint droplets and pipe walls, the interface strength of interior paint liner is changed as the paint droplets are deposited on the wall, which becomes the dominant source of the droplet adhesion during spray coating. This article aims to study the droplet distributions with changing rotation speed of rotary sprayer in an airless spray coating process. The contact interactions of collisions between paint droplets and the pipe wall were studied in an airless spray coating process, realizing in a high-strength paint protective liner using centrifugal spraying technology. The methodology was based on the discrete element method (EDEM) with JKR contact model, assuming paints as discrete phase. The calibration method of surface energy used in JKR contact model was proposed using a virtual repose angle test. The virtual accumulation angle was obtained from the paint droplet pile. The surface energy was determined according to the variations of accumulation angles. The droplet discharge velocity equation of sprayer holes was derived based on the motion equation of droplets under the action of the centrifugal field. The expression represented a relationship between paint droplet discharge velocity and sprayer rotation speed. Simulated results showed that the paint droplet accumulation angles changed from a moderating region, transitioning to an increasing region with increasing surface energies. The higher the surface energy, the larger the accumulation angle, resulting in a high height of the paint droplet pile. The threshold value was found from the intersection between the moderating region and increasing region. The value of surface energy was found to be 32.7 J/m2 from the statistical analyses of the repose angle virtual test. Simulations showed that the exit droplet velocity of sprayer holes increased with the increase of rotation speed and sprayer diameter. These droplet velocities were induced by centrifugal forces due to sprayer rotation. The larger the sprayer size, the higher the exit droplet velocity. The equation of exit droplet velocity was correlated with discharge coefficient. Results indicated that the paint droplet discharge coefficient of holes was nearly constant as a function of dimensionless Froude numbers. The characteristics of paint droplets were simulated with changing rotation speed in an airless coating process. The paint droplet numbers increased with times. The change of droplet numbers can be roughly divided into three stages:an initial stage, a transition stage and stable stage with times. Results indicated that the number of paint droplets on the pipe inner wall decreased with the increase of sprayer rotation speed, suggesting that a reasonable rotation speed was helpful to increase the number of paint droplets on the pipe inner wall. The paint droplet number was the largest at the rotation speed of 2 500 r/min with the large standard deviation and relative error. The standard deviation and relative error of paint droplet numbers were reduced with the increase of rotation speeds. It can be inferred that the rotation speed of the rotary sprayer is suggested not less than 5 000 r/min in order to obtain a uniformity of paint droplets in an airless paint droplet spray coating process. |
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