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Bulletin of Engineering Geology and the Environment

Erschienen in:

18.02.2021 | Original Paper

Evaluating the influence of engineering geological parameters on TBM performance during grinding process in limestone strata

verfasst von: Seyed Mahdi Pourhashemi, Kaveh Ahangari, Jafar Hassanpour, Seyed Mosleh Eftekhari

Erschienen in: Bulletin of Engineering Geology and the Environment | Ausgabe 4/2021

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Abstract

The chipping and grinding processes are the basis for understanding rock cutting during TBM excavation in hard rock conditions. The chips are produced when tensile fractures created by adjacent cutters propagate parallel to the tunnel face and coalesce whereas grinding occurs when fractures do not fully propagate through the rock and only fines are generated. Chipping is the normal and efficient boring process using machines equipped with disc cutters. Consequently, almost all of the models proposed for predicting the TBM penetration have been developed by the assumption that chipping is the dominant mode. It is obvious that these models are unable to predict correctly TBM performance when grinding is dominated in the rock cutting process. In this study, the relationships between engineering geological properties of the rock units (Cretaceous limestones) and operating and performance parameters of a refurbished EPB-TBM, employed for completion of SEL6 (the Southern Extension of Line 6, Tehran Metro) tunnel, were evaluated and analyzed. In this project due to limitations in the load capacity of the employed cutters and insufficient initial penetration in rock, the excavation was mostly carried out on grinding-dominated mode. So, the suitable data for establishing a special database and consequent analyses were provided. The established database composed of actual operating and performance parameters of the machine (i.e., cutterhead penetration and RPM and cutter load) and also engineering geological properties (i.e., UCS, alpha angle, GSI, and RQD) of limestone strata. Finally, by statistical analyses performed on collected and screened data (41 data sets), some simple, site-specific, empirical equations were developed to predict the TBM performance on grinding mode. In addition, according to the multivariate regression method, a significant relationship between the cutterhead penetration (PRev), the cutter load (Fn), intact rock strength (UCS), and geological strength index (GSI) was established, statistically. The obtained results demonstrate that this engineering geological-based model could provide a new applicable equation for accurately predicting TBM performance for similar geological conditions where grinding is dominant.

Vorheriger Artikel A method for detecting and pretreating boulders during shield tunneling in granite strata

Nächster Artikel The effect of rock weathering and transition zones on the performance of an EPB-TBM in complex geology near Istanbul, Turkey

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Armetti G, Migliazza MR, Ferrari F et al (2018) Geological and mechanical rock mass conditions for TBM performance prediction. The case of “La Maddalena” exploratory tunnel, Chiomonte (Italy). Tunn Undergr Sp Technol 77:115–126CrossRef

Balci C, Bilgin N (2007) Correlative study of linear small and full-scale rock cutting tests to select mechanized excavation machines. Int J Rock Mech Min Sci 44:468–476CrossRef

Berdal T, Jakobsen PD, Jacobsen S (2018) Utilising excavated rock material from tunnel boring machines (TBMs) for concrete. SynerCrete’ 8 International Conference on Interdisciplinary Approaches for Cement-based Materials and Structural Concrete, Funchal, Madeira Island, Portugal.

Brino G, Peila D, Steidl A, Fasching F (2015) Prediction of performance and cutter wear in rock TBM: application to Koralm tunnel project. GEAM-GEOINGEGNERIA Ambient E MINERARIA-GEAM-GEOENGINEERING. Environ Min:37–50

Bruland A (1998) Hard rock tunnel boring, vol 1–10

Delisio A, Zhao J, Einstein HH (2013) Analysis and prediction of TBM performance in blocky rock conditions at the Lötschberg Base Tunnel. Tunn Undergr Sp Technol 33:131–142CrossRef

Farmer IW, Glossop NH (1980) Mechanics of disc cutter penetration. Tunnels Tunn 12:22–25

Farrokh E, Rostami J, Laughton C (2012) Study of various models for estimation of penetration rate of hard rock TBMs. Tunn Undergr Sp Technol 30:110–123CrossRef

Firouzei Y, Hassanpour J, Pourhashemi SM (2019) Tunneling with a soft rock EPB machine in hard rock conditions, the experience of Tehran metro line 6 southern expansion sector. In: 4th International Conference on Tunnel Boring Machines in Difficult Grounds. Denver, USA

Frenzel C, Galler R, Käsling H, Villeneuve M (2012) Penetration tests for TBMs and their practical application/Penetrationstests für Tunnelbohrmaschinen und deren Anwendung in der Praxis. Geomech Tunn 5:557–566CrossRef

Frenzel C, Käsling H, Thuro K (2008) Factors influencing disc cutter wear. Geomech Tunnelbau Geomech Tunnelbau 1:55–60CrossRef

Gong Q, Zhao J (2009) Development of a rock mass characteristics model for TBM penetration rate prediction. Int J Rock Mech Min Sci 46:8–18CrossRef

Graham PC, PC G (1976) Rock exploration for machine manufacturers.

Gunsallus KL, Kulhawy FH (1984) A comparative evaluation of rock strength measures. In: International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts. Elsevier, Amsterdam, pp 233–248

Hassanpour J, Rostami J, Zhao J (2011) A new hard rock TBM performance prediction model for project planning. Tunn Undergr Sp Technol 26:595–603CrossRef

Hassanpour J, Rostami J, Zhao J, Tarigh Azali S (2015) TBM performance and disc cutter wear prediction based on ten years’ experience of TBM tunneling in Iran. Geomech Tunnelbau 8(3):239–247CrossRef

Hassanpour J, Firouzei Y, Hajipour G (2020) Actual performance analysis of a double shield TBM through sedimentary and low to medium grade metamorphic rocks of Ghomrood Water Conveyance Tunnel Project (Lots 3 & 4). Bull Eng Geol Environ, under production. https://doi.org/10.1007/s10064-020-01947-z

Hoek E, Marinos P, Benissi M (1998) Applicability of the Geological Strength Index (GSI) classification for very weak and sheared rock masses. The case of the Athens Schist Formation. Bull Eng Geol Environ 57:151–160CrossRef

ISRM (1978) Suggested methods for the quantitative description of discontinuities in rock masses. Int J Rock Mech Min Sci Geomech Abstr 15:319–368CrossRef

ISRM (1985) Suggested method for determining point load strength. Int J Rock Mech Min Sci Geomech Abstr 22:51–60CrossRef

Koopialipoor M, Tootoonchi H, Armaghani DJ et al (2019) Application of deep neural networks in predicting the penetration rate of tunnel boring machines. Bull Eng Geol Environ 78:6347–6360CrossRef

Labra C, Rojek J, Onate E (2017) Discrete/finite element modelling of rock cutting with a TBM disc cutter. Rock Mech Rock Eng 50:621–638CrossRef

Lazemi HA, Dehkordi MS (2019) Estimation of the TBM penetration rate using the post-failure behavior of a rock mass and the equivalent thrust per cutter. A case study: the Amirkabir Water Transferring Tunnel of Iran. Bull Eng Geol Environ 78:1735–1746CrossRef

Marinos P, Hoek E (2001) Estimating the geotechnical properties of heterogeneous rock masses such as flysch. Bull Eng Geol Environ 60:85–92CrossRef

Marinos V (2019) A revised, geotechnical classification GSI system for tectonically disturbed heterogeneous rock masses, such as flysch. Bull Eng Geol Environ 78:899–912CrossRef

Marinos V, Marinos P, Hoek E (2005) The geological strength index: applications and limitations. Bull Eng Geol Environ 64:55–65CrossRef

Rahsaz-Tarh Consulting Engineers (2016) Engineering geological investigation report of Southern Extension of Tehran Metro Line, p 6

Salimi A, Rostami J, Moormann C, Hassanpour J (2018) Examining feasibility of developing a rock mass classification for hard rock TBM application using non-linear regression, regression tree and generic programming. Geotech Geol Eng 36(2):1145–1159

Tarigh Azali S, Ghafoori M, Lashkaripour GR, Hassanpour J (2013) Engineering geological investigations of mechanized tunneling in soft ground: a case study, East–West lot of line 7, Tehran Metro, Iran. Eng Geol 166:170–185CrossRef

Tarigh Azali S, Pourhashemi SM, Khorasani E (2018) NATM Tunneling in urban area, a review of planning, executing, and monitoring in Tehran Metro Line 6. In: ITA - AITES WORLD TUNNEL CONGRESS (WTC 2018). Dubai

Villeneuve M (2008) Examination of geological influence on machine excavation of highly stressed tunnels in massive hard rock

Villeneuve MC (2017) Hard rock tunnel boring machine penetration test as an indicator of chipping process efficiency. J Rock Mech Geotech Eng 9:611–622CrossRef

Villeneuve MC, Diederichs MS, Kaiser PK (2012) Effects of grain scale heterogeneity on rock strength and the chipping process. Int J Geomech 12:632–647CrossRef

Yagiz S (2008) Utilizing rock mass properties for predicting TBM performance in hard rock condition. Tunn Undergr Sp Technol 23:326–339CrossRef

Zhou J, Yazdani Bejarbaneh BJA, Danial TMM (2020) Forecasting of TBM advance rate in hard rock condition based on artificial neural network and genetic programming techniques. Bull Eng Geol Environ 79:2069–2084CrossRef

Titel: Evaluating the influence of engineering geological parameters on TBM performance during grinding process in limestone strata
verfasst von: Seyed Mahdi Pourhashemi
Kaveh Ahangari
Jafar Hassanpour
Seyed Mosleh Eftekhari
Publikationsdatum: 18.02.2021
Verlag: Springer Berlin Heidelberg
Erschienen in: Bulletin of Engineering Geology and the Environment / Ausgabe 4/2021
Print ISSN: 1435-9529
Elektronische ISSN: 1435-9537
DOI: https://doi.org/10.1007/s10064-021-02134-4

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