بررسی اثر مقیاس بر پارامترهای هندسی سطوح درزه سنگ

نوع مقاله : مقاله پژوهشی

نویسندگان

1 گروه معدن، دانشگاه سیستان و بلوچستان

2 گروه مهندسی مکانیک سنگ، دانشگاه تربیت مدرس

10.29252/anm.8.15.99

چکیده

بر اساس مطالعات انجام شده، مشخص شده است که رفتار مکانیکی درزه‌های سنگی می‌تواند به عنوان تابعی از مقیاس تغییر کند. در چهل سال گذشته، مطالعات وسیعی بر روی اثر مقیاس بر روی رفتار مکانیکی درزه‌های سنگی انجام شده است. بسیاری از این مطالعات نتایج متناقضی را در بر داشته است. بنابراین ماهیت و سازوکار اثر مقیاس بر رفتار مکانیک درزه‌های سنگی هنوز به طور کامل شناخته نشده و نیاز به مطالعات بیشتری دارد. یکی از مهم‌ترین پارامترهایی که بر روی رفتار برشی درزه‌ها تاثیر گذار است خصوصیات هندسی سطوح آنها است. بنابراین بررسی پارامترهای هندسی سطوح درزه با در نظر گرفتن اثر مقیاس بر آنها تا حد زیادی می‌تواند تبیین کننده رفتار وابسته به مقیاس درزه‌ها باشد. در پژوهش حاضر سه سطح طبیعی درزه با هندسه‌های متفاوت و با ابعاد بیش‌تر از 2500 سانتی‌مترمربع از طبیعت انتخاب شده‌اند. برای ابعاد 50 × 50 میلی‌مترمربع تا 500 × 500 میلی‌مترمربع، پارامترهای هندسی مهم درزه محاسبه شده و اثر مقیاس بر این پارامترها و تغییرات مقادیر آن‌ها نسبت به مقیاس مورد بررسی قرار گرفته است. بررسی‌های انجام شده نشان می‌دهد اثر مقیاس بر پارامترهای مختلف هندسی یکسان نبوده و بسته به نوع هندسه درزه و چگونگی توزیع پارامترهای زبری اولیه و ثانویه سطح، نتایج متفاوتی را به همراه خواهد داشت. پارامترهای زاویه‌ای سطح درزه در مقیاس بیشتر از‏‎‎‏400 سانتی‌مترمربع تقریبا مستقل از مقیاس ‏خواهند شد. اما پارامترهای ارتفاعی سطح درزه، برای سطوحی که زبری درجه اول در آنها ‏بیش‌تر باشد، با افزایش مقیاس (حداقل تا‏ 2500 سانتی‌مترمربع) افزایش می‌یابند. ‏

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

The effect of scale on the geometric parameters of the rock joint surfaces

نویسندگان [English]

  • Mohamad Javad Azinfar 1
  • Abdolhadi Ghazvinian 2
  • Hamid Reza Nejati 2
1 Dept. of Mining, University of Sistan and Baluchestan
2 Tarbiat Modares University
چکیده [English]

Summary
In this study, three different natural joint geometries in dimensions greater than 2500 cm2 were selected from the field. The geometric parameters of the surface joints have been calculated from the scale of 50 × 50 mm2 to 500 × 500 mm2 and the effect of scale on these parameters and their variations with scale has been discussed.
 
Introduction
The scale dependency of discontinuity surface roughness and shear strength has been investigated by many other researchers over the last three decades. Many of these studies have produced conflicting results. Some studies have shown a decrease in strength and roughness with increasing discontinuity size. Other studies have shown the existence of positive scale effects, a combination of positive and negative scale effects, or no scale effect. The present study attempts to investigate the effect of scale on the geometrical properties of rock joints.
 
Methodology and Approaches
In this study, three natural smooth, undulating and stepped rock joints were prepared and their surfaces were scanned by 3D optical scanner. The surfaces were digitized and the geometric parameters were calculated by the code written in Matlab software. The geometric parameters were calculated for the square widows that were centered at the same locations and were measured from 50 × 50 mm2 to 500 × 500 mm2.
 
Results and Conclusions
The results showed that the effect of scale on various geometric parameters are not the same and will have different results depending on the distribution of primary (waviness) and secondary (unevenness) roughness. The angular parameters of rock joint surfaces, in the scale of greater than 400 cm2, are independent of scale. However the amplitude parameters of rock joint surfaces, in the surfaces with dominant waviness, increase with increasing of scale (at least up to 2500 cm2)

کلیدواژه‌ها [English]

  • Scale effect
  • Geometric characteristics of joint surfaces
  • Geometric parameters of the surfaces
  • 3D scannig of rock joint
  • 3D Optical scanner

مراجع

[1]           Barton N, Choubey V. 1977. “The shear strength of rock joints in theory and practice”. Rock Mech and rock engineering.10:1–54.
[2]           ‎Bandis S, Lumsden AC, Barton NR. 1981. “Experimental studies of scale effects on the shear behavior of rock joints”. Int J Rock Mech Min Sci Geomech Abstr 18(1):1–21.
[3            Hencher, S. R., Toy, J.P., Lumsden, A.C., 1993. “Scale dependent shear strength of rock joints.” Second International Workshop on Scale Effects in Rock Masses. Taylor & Francis‏,‏‎ Lisbon, Portugal, pp. 233–240‏.‏
[4]           ‎Cravero M, Iabichino G, Piovano V. 1995. “Analysis of large joint profiles related to rock slope instabilities”. In: 8th ISRM congress, Tokyo, Japan, 25–29 September 1995. A.A. Balkema, Rotter- dam, pp 423–428.
[5]           ‎Cravero M, Iabichino G, Ferrero AM. 2001. “Evaluation of joint roughness and dilatancy of schistosity joints”. In: Sarkka P, Eloranta P (Eds) Rock mechanics—a challenge for society; proceedings of Eurock 2001, Espoo, Finland, 4–7 June 2001.‏ ‏
[6]           ‎Leal Gomes, M.J.A., 2003. “Some new essential questions about scale effects on the mechanics of rock mass joints.” 10th ISRM Congress: Technology Roadmap for Rock Mechanics. South African Institute of Mining and Metallurgy, Vila Real, pp. 721–728‏.‏‎
[7]           ‎Fardin, N., Stephansson, O., Jing, L., 2001. “The scale dependence of rock joint surface roughness.” Int. J. Rock Mech. Min. Sci. 38, 659–669.
[8]           ‎Fardin, N., Feng, Q., Stephansson, O., 2004. “Application of a new in situ 3D laser scanner to study the scale effect on the rock joint surface roughness.” Int. J. Rock Mech. Min. Sci‏.‏‎ 41, 329–335.
[9]           ‎Fardin N. 2008. “Influence of structural non-stationarity of surface roughness on morphological characterization and mechanical deformation of rock joints”. Rock Mech Rock Eng.
[10]         ‎Tatone, B.S.A., Grasselli, G., 2012. “An investigation of discontinuity roughness scale dependency using high-resolution surface measurements. Rock Mech. Rock. Eng. 1–25.
[11]         ‎‎ISRM, 1978. International Society for Rock Mechanics commission on standardization of laboratory and field tests: “suggested methods for the quantitative description of discontinuities in rock masses.” Int J Rock Mech Min Sci Geomech Abstr 15(6): 319–368.
[12]         ‎Chae BG, Ichikawa Y, Jeong GC, Seo YS, Kim BC. 2004. “Roughness measurement of rock discontinuities using a confocal laser scanning microscope and the Fourier spectral analysis.” Eng Geol 72(3–4):181–199.
[13]         ‎Lee H-S, Ahn K-W. 2004. “A prototype of digital photogrammetric algorithm for estimating roughness of rock surface.” Geosci J 8(3):333–341.
[14]         ‎Haneberg W. 2007. “Directional roughness profiles from three- dimensional photogrammetric or laser scanner point clouds.” In: Eberhardt E, Stead D, Morrison T (eds) Rock mechanics: meeting society’s challenges and demands; proceedings of the 1st Canada–US rock mechanics symposium, Vancouver, Can- ada, 27–31 May 2007. Taylor and Francis, London, pp 101–106.
[15]         ‎Baker BR, Gessner K, Holden E-J, Squelch AP. 2008. “Automatic detection of anisotropic features on rock surfaces.” Geosph 4(2): 418–428.
[16]         Grasselli G, Wirth J, Egger P. 2002. “Quantitative three-dimensional description of a rough surface and parameter evolution with shearing.” Int J Rock Mech Min Sci 39(6):789–800.
[17]         Hong ES, Kwon TH, Song KI. Cho GC. 2006. “Observation of the Degradation Characteristics and Scale of Unevenness on Three-dimensional Artificial Rock Joint Surfaces Subjected to Shear.” Rock Mech Rock Eng 49:3–17.
[18]         Nasseri MHB, Tatone BSA, Grasselli G, Young RP. 2009. “Fracture toughness and fracture roughness interrelationship in thermally treated Westerly granite.” Pure Appl Geophys 166(5): 801–‎‎822.
[19]         Lanaro F. 2000. “A random field model for surface roughness and aperture of rock fractures.” Int J Rock Mech Min Sci 37:1195–210.‏ ‏
[20]         Belem T, Homand-Etienne F, Souley M. 1997. “Fractal analysis of shear joint roughness.” Int J Rock Mech Min Sci 34: (3–4), Paper No. 130.
[21]         Tatone, B.S.A., Grasselli, G., 2009. “A method to evaluate the three-dimensional roughness of fracture surfaces in brittle geomaterials. Rev. Sci. Instrum. 80, 1–10.
[22]         Grasselli G. 2001. “Shear strength of rock joints based on quantified surface description.” Ph.D. thesis, Univ. Polytechnique Federale de Lausanne.
[23]         Malinverno, A., 1990. “A simplemethod to estimate the fractal dimension of a self-affine series.” Geophys. Res. Lett. 17, 1953–1956‏.‏‎ Mas Ivars, D., Pierce, M.E., Darcel, C., Reyes-Montes, J., Potyondy, D.O., Young, R.P‏.,‏‎
[24]         Kulatilake PHSW, Um J. 1999. “Requirements for accurate quanti- fication of self-affine roughness using the roughness-length method.” Int J Rock Mech Min Sci 36(1):5–18.
[25]         Orey S. 1970. “Gaussian simple functions and Hausdorff dimension of level crossing.” Z. Wahrscheinlichkeitstheor. Verw Gebiete ;15:249–56.
[26]         Odling NE. 1994. “Natural fracture profiles, fractal dimension and joint roughness coefficient.” Rock Mech Rock Eng;27:135–53.
[27]         Berry MV, Lewis ZV. 1980. “On the Weierstrass-Mandelbrot fractal function.” R Soc London Proc Ser A;370:459–84.
[28]         El Soudani, S. M. 1978. “Profilometric analysis of fractures.” Metallography, 11, 247-336.
[29]         Lange D. A., Jennings H. M. & Shah S. P. 1993. “Relationship between fracture surface roughness and fracture behaviour of cement paste and mortar.” J. Am. Ceram. Soc., 3, 589-597.
[30]         Gokhale, A. M. Underwood E. E. 1990. “A general method for estimation of fracture surface roughness: Part I. Theoretical aspects.” Mechanical Behavior Metallurgical Transactions A. Volume ‎‎21, Issue 5, pp 1193-1199.‏ ‏
[31]         Lee, H. S. & Ahn, K. W. 2004. “A Prototype of Digital Photogrammetric Algorithm for Estimating Roughness of Rock Surface. Geosciences, 8/ 3: 333-341.
[32]         Belem T, Homand-Etienne F, Souley M. 2000. “Quantitative parameters for rock joint surface” roughness. Rock Mech Rock Eng 33(4):217–242.
[33]         American standard Association. 1955. “Surface roughness, waviness and lay,” ASA B46.1.
[34]         Myers M. O. 1962. “Characterization‏ ‏of surface roughness.” Wear 5, P 182-189.
روش های تحلیلی و عددی در مهندسی معدن
دوره 8، شماره 15
تیر 1397
صفحه 99-114

فایل ها

سابقه مقاله

  • تاریخ دریافت: 03 خرداد 1395
  • تاریخ بازنگری: 18 شهریور 1397
  • تاریخ پذیرش: 30 خرداد 1395

هم رسانی

ارجاع به این مقاله

آمار