MEASUREMENT OF ADHESION FORCES IN AIR WITH THE VIBRATION METHOD 被引量：7

MEASUREMENT OF ADHESION FORCES IN AIR WITH THE VIBRATION METHOD

导出

摘要 The vibration method represents a practical method for the measurement of adhesion forces and adhesion force distributions. This method causes sinusoidally alternating stresses and yields detachment and contact forces between particles and substrate of the same order of magnitude. Alternating contact forces of the vibration method can cause an adhesion force intensification through flattening of asperities. The measuring principle of the vibration method and the analysis of experimental results are described in the article. Normal adhesion forces (pull-off forces) are measured using the vibration method and the colloidal probe technique. The results of both methods show good agreement for small particle sizes. The influence of the detachment force direction is shown by comparing tangential and normal adhesion forces measured using particle reentrainment in a turbulent air flow and the vibration method, respectively. The surface roughness of the substrate and the relative humidity are shown to significantly influence the measured adhesion forces. For the calculation of the adhesion forces, an approach by Rabinovich was combined with approximations of plastic micro asperity flattening. The Rabinovich approach accounts for roughness effects on the van der Waals force by incorporating the rms roughness of the interacting surfaces, rms-values of the particles and substrates were measured with atomic force microscopy at different scanning areas. The vibration method represents a practical method for the measurement of adhesion forces and adhesion force distributions. This method causes sinusoidally alternating stresses and yields detachment and contact forces between particles and substrate of the same order of magnitude. Alternating contact forces of the vibration method can cause an adhesion force intensification through flattening of asperities. The measuring principle of the vibration method and the analysis of experimental results are described in the article. Normal adhesion forces (pull-off forces) are measured using the vibration method and the colloidal probe technique. The results of both methods show good agreement for small particle sizes. The influence of the detachment force direction is shown by comparing tangential and normal adhesion forces measured using particle reentrainment in a turbulent air flow and the vibration method, respectively. The surface roughness of the substrate and the relative humidity are shown to significantly influence the measured adhesion forces. For the calculation of the adhesion forces, an approach by Rabinovich was combined with approximations of plastic micro asperity flattening. The Rabinovich approach accounts for roughness effects on the van der Waals force by incorporating the rms roughness of the interacting surfaces, rms-values of the particles and substrates were measured with atomic force microscopy at different scanning areas.

作者 Siegfried Ripperger Konrad Hein

机构地区 Lehrstuhl für Mechanische Verfahrenstechnik Lehrstuhl für Mechanische Verfahrenstechnik

出处《China Particuology》 SCIE EI CAS CSCD 2005年第1期3-9,共7页

关键词 adhesion force vibration method ROUGHNESS adhesion force, vibration method, roughness

分类号 TQ02 [化学工程]

引文网络
相关文献

参考文献10

1[1]Deryaguin, B. V. & Zimon, A. D. (1961). Adhesion of powder particles to plane surfaces. Kolloidnyi Zhurnal, 23(5), 544-552.
2[2]Heim, L. O., Blum, J., Preuss, M. & Butt, H. J. (1999). Adhesion and friction forces between spherical micrometer-sized particles.Phys. Rev. Lett., 83(16), 3328-3331.
3[3]Hein, K., Hucke, T., Stintz, M. & Ripperger, S. (2002). Analysis of adhesion forces between particles and wall based on the vibration method. Part. Part. Syst. Char., 19, 269-276.
4[4]Hertz, H. J. (1881). Reine Angewandte Math., 92, 156.
5[5]Kappl, M. & Butt, H. (2002). The colloidal probe technique and its application to adhesion force measurements. Part. Part. Syst.Char., 19, 129-143.
6[6]Matsusaka, S., Koumura, M. & Masuda, H. (1988). Analysis of adhesive force between particle and wall based on particle reentrainment and centrifugal separation, Artikel 51- World Congress on Particle Technology 3.
7[7]Rabinovich, Y. I. & Moudgil, M. (2000). Adhesion between nanoscale rough surfaces. J. Colloid Interface Sci., 232, 10-24.
8[8]Ripperger, S. & Hein, K. (2005). Measurement of adhesion forces between particles and rough substrates in air with the vibration method. KONA, in press.
9[9]Rumpf, H., Sommer, K. & Steier, K. (1976). Mechanismen der Haftkraftverstarkung bei der Partikelhaftung durch plastisches Verformen, Sintern und viskoelastisches FlieBen. Chem. lng.Tech., 48, 300-307.
10[10]Zhou, H. & Peukert, W. (2004). Tailoring particle-substrate adhesion, Oral Presentation 25.5 at the International Congress for Particle Technology 2004, Nuremberg.

同被引文献40

1夏长念,吴超,贺兵红.微粒子粘附、清除和预防的研究成果综述[J].清洗世界,2006,22(12):24-29. 被引量：3
2Desa J, Zhong Q, Ergezen E, et ol. Microparticle manipulation on the surface of a piezoeeramie actuator [J]. Measurement Science and Technology, 2010, 21(10): 1-13.
3Felieetti M A, Salazar-Banda G R, Coury J R, et al. Influence of particle size, applied compression, and substratum material on particle-surface adhesion force using the centrifuge technique [J]. Industrial & Engineering Chemistry Research, 2009, 48(2): 877-887.
4Xing M, Zhong W, Xu X L, et al. Adhesion force studies of nanofibers and nanopartieles[J]. Langmuir, 2010, 26(14): 11809-11814.
5Strathmann S C, Murphy M A, Goeekner B A, et ol. Forces between insulin microspheres and polymers surfaces for a dry powder inhaler[J]. International Journal of Pharmaceutics, 2009, 372(1-2): 147-153.
6Thomas G, Ouabbas Y, Grosseau P, et ol. Modeling the mean interaction forces between powder particles. Application to silica gel-magnesium stearate mixtures[J]. Applied Surface Science, 2009, 255(17): 7500-7507.
7Davies M J, Brindley A, Chen X Y, et al. A quantitative assessment of inhaled drug particle-pulmonary surfactant interaction by atomic force microscopy[J]. Colloids and Surfaces B: Biointerfaces, 2009, 73(1): 97-102.
8Farshchi-Tabrizi M, Kappl M, Cheng Y J, et ol. On the adhesion between fine particles and nanocontacts: An atomic force microscope study[J]. Langmuir, 2006, 22(5): 2171-2184.
9Ding W, Zhang H, Cetinkaya C. Rolling resistance moment-based adhesion characterization of microspheres [J]. The Journal of Adhesion, 2008, 84(12): 996-1006.
10Burtovyy R, Liu Y, Zdyrko B, et ol. AFM measurements of interactions between CMP slurry particles and substrate [J]. Journal of the Electrochemical Society, 2007, 154(6): 476-4851.

引证文献7

1钟剑,吴超.微颗粒黏附力测试技术研究进展[J].科技导报,2012,30(3):67-73. 被引量：1
2钟剑,吴超,黄锐.微颗粒黏附力测试的空气动力学模型[J].中南大学学报（自然科学版）,2012,43(1):287-292. 被引量：3
3夏世祥.油菜籽现代加工技术[J].四川粮油科技,2000,17(1):23-24.
4Karina A.Valenzuela Aracena,Jesica G.Benito,Luc Oger,Irene Ippolito,Rodolfo O.Ufiac,Ana M.Vidales.Frequency-amplitude behavior in the incipient movement of grains under vibration[J].Particuology,2018,16(5):1-9. 被引量：2
5F.J.Balladore,J.G.Benito,R.O.Unac,A.M.Vidales.Mineral dust resuspension under vibration: Onset conditions and the role of humidity[J].Particuology,2020,18(3):112-119.
6Karina de los Angeles Valenzuela Aracena,Rodolfo O.Unac,Irene Ippolito,Ana M.Vidales.Movement initiation of millimeter particles on a rotating rough surface: The role of adhesion[J].Particuology,2020,18(6):92-99. 被引量：1
7Sofia Eirini Chatoutsidou,Mihalis Lazaridis.Resuspension of spherical particles due to surface vibration[J].Particuology,2021,19(1):126-135. 被引量：2

二级引证文献9

1王国志,孙海振,吴文海,柯坚,刘红现.棒状绝缘子动态积污模型[J].电瓷避雷器,2017(4):165-170. 被引量：1
2杨宁,王盼,张荣标,徐佩锋,孙俊,毛罕平.基于富集微流控芯片的稻曲病菌孢子光电检测方法[J].农业工程学报,2017,33(20):161-168. 被引量：3
3Karina de los Angeles Valenzuela Aracena,Rodolfo O.Unac,Irene Ippolito,Ana M.Vidales.Movement initiation of millimeter particles on a rotating rough surface: The role of adhesion[J].Particuology,2020,18(6):92-99. 被引量：1
4Sofia Eirini Chatoutsidou,Mihalis Lazaridis.Resuspension of spherical particles due to surface vibration[J].Particuology,2021,19(1):126-135. 被引量：2
5黄正梁,洪颖,田思航,杨遥,王靖岱,阳永荣.聚乙烯颗粒间范德华力的原子力显微镜测量[J].化学反应工程与工艺,2020,36(4):319-324. 被引量：2
6Lizhuo Zhu,Haifeng Lu,Xiaolei Guo,Haifeng Liu.Structural relaxation and avalanche dynamics of particle piles under vertical vibration[J].Particuology,2022,20(9):65-74.
7周世华,王云贺,陈雨,任朝晖.非线性振动下卸载系统动力学及运动学特性分析[J].东北大学学报（自然科学版）,2022,43(12):1724-1731.
8Chuannan Li,Jie Chen,Changbo Jiang,Xie Li,Zhiyuan Wu.Experimental investigation about the incipient velocity of spherical particles on a hemispherical bed surface[J].Particuology,2024,88(5):49-61.
9杨成楠,吴超.纳米流体的化学抑尘性能试验研究[J].中国安全科学学报,2019,29(2):147-152. 被引量：4

1M F Ashby.材料问题物理模型的建立[J].力学进展,1993,23(4):560-573. 被引量：1
2李田泽.使用莫尔条纹法测量气流密度[J].光学技术,1997,23(6):1-4. 被引量：2
3Eberhard Schmidt.INVESTIGATIONS INTO THE DETACHMENT OF DIFFERENTLY STRUCTURED DUST LAYERS FROM SURFACES[J].China Particuology,2005,3(1):10-13. 被引量：1
4于韶山,王景刚,鲍玲玲.带回热器的R404a/CO_2复叠式制冷系统的理论分析[J].河北工程大学学报（自然科学版）,2015,23(4):75-77. 被引量：1
5QI Zhiwen.Intensifi cation Mechanism and Processes[J].Bulletin of the Chinese Academy of Sciences,2014,28(2):154-156.
6徐阜新.研究纳米材料对浆料性能的影响[J].建材与装饰（上旬）,2016,0(11):163-164. 被引量：1
7Yan Zhang,Lian-Meng Wang,En-Zhong Tan,Shi-He Yang,Li-Dong Li,Lin Guo.Uniform arrays of gold nanoparticles with different surface roughness for surface enhanced Raman scattering[J].Chinese Chemical Letters,2015,26(11):1426-1430. 被引量：2
8丁保华,李文超,王福明,仲维斌.分形理论及其在无机材料烧结与氧化过程中的应用[J].硅酸盐通报,1999,18(3):64-68. 被引量：10
9RIMLYAND V I,BAKHANTSOV A V,STARIKOVA V N.Dynamics of acousto-rheological properties of polymerized materials on their solidification[J].Rare Metals,2007,26(S1):1-4.
10招润华.探讨PET膜用UV硬化液的配制及涂层性能[J].化工管理,2015(32):121-122.

China Particuology

2005年第1期

浏览历史

内容加载中请稍等...

MEASUREMENT OF ADHESION FORCES IN AIR WITH THE VIBRATION METHOD 被引量：7

参考文献10

同被引文献40

引证文献7

二级引证文献9

相关作者

相关机构

相关主题

浏览历史