Further titles in this series: 1. G. SANGLERAT, THE PENETROMETER AND SOIL EXPLORATION 2. Q. ZARUBA AND V, MENCL, LANDSLIDES AND THEIR CONTROL 3. E. E. WAHLSTROM, TUNNELING IN ROCK 4. R. SILVESTER, COASTAL ENGINEERING, I and II 5. R. N. YOUNG AND B. P. WARKENTIN, SOIL PROPERTIES AND BEHAVIOUR 6. E. E. WAHLSTROM, DAMS, DAM FOUNDATIONS, AND RESERVOIR SITES 7. W. F. CHEN, LIMIT ANALYSIS AND SOIL PLASTICITY 8.L. N. PERSEN, ROCK DYNAMICS AND GEOPHYSICAL EXPLORATION. Introduction to Stress Waves in Rocks 9. M. D. GIDIGASU, LATERITE SOIL ENGINEERING 10. Q. ZARUBA AND V. MENCL, ENGINEERING GEOLOGY W.H.K. GUPTA AND B. K. RASTOGI, DAMS AND EARTHQUAKES 12. F. H. CHEN, FOUNDATIONS ON EXPANSIVE SOILS 13. L. HOBST AND J. ZAJIC, ANCHORING IN ROCK 14. B. VOIGT (Editor), ROCKSLIDES AND AVALANCHES, 1 and 2 15. C. LOMNITZ AND E. ROSENBLUETH, SEISMIC RISK AND ENGINEERING DECISIONS 16. C. A. BAAR, APPLIED SALT-ROCK MECHANICS, 1. The In-Situ Behavior of Salt Rocks 17. A. P. S. SELVADURAI, ELASTIC ANALYSIS OF SOIL-FOUNDATION INTERAC- TION 18. /. FEDA, STRESS IN SUBSOIL AND METHODS OF FINAL SETTLEMENT CALCULATION 19. A. KEZDI, STABILIZED EARTH ROADS 20. E. W. BRAND AND R. P. BRENNER (Editors), SOFT-CLAY ENGINEERING 2\.A. MYSLIVEC AND Z. KYSELA, THE BEARING CAPACITY OF BUILDING FOUNDATIONS 22. R. N. CHOWDHURY, SLOPE ANALYSIS 23. P. BRUUN, STABILITY OF TIDAL INLETS. Theory and Engineering 24. Z. BAZANT, METHODS OF FOUNDATION ENGINEERING 25. A. KEZDI, SOIL PHYSICS. Selected Topics 26. H. L. JESSBERGER (Editor), GROUND FREEZING 27. D. STEPHENSON, ROCKFILL IN HYDRAULIC ENGINEERING 28. P. E. FRIVIK, N. JANBU, R. SAETERSDAL AND L. I. FINBORUD (Editors), GROUND FREEZING 1980 29. P. PETER, CANAL AND RIVER LEVEES 30. /. FEDA, MECHANICS OF PARTICULATE MATERIALS. The Principles 31. Q. ZARUBA AND V. MENCL, LANDSLIDES AND THEIR CONTROL. Second completely revised edition 32. /. W. FARMER (Editor), STRATA MECHANICS 33. L. HOBSTAND J. ZAJIC, ANCHORING IN ROCK AND SOIL. Second completely revised edition Developments in Geotechnical Engineering 33 ANCHORING IN ROCK AND SOIL second completely revised edition by Dr. Ing. LEOS HOBST Research Institute oj Civil Engineering, Brno ( VU1S) and Ing. JOSEF ZAJIC CSc Engineering Geology, Prague (Stavebni geologie) ELSEVIER SCIENTIFIC PUBLISHING COMPANY Amsterdam Oxford New York 1983 Published in co-edition with SNTL Publishers of Technical Literature, Prague Distribution of this book is being handled by the following publishers: for the USA and Canada ELSEVIER SCIENCE PUBLISHING COMPANY, INC. 52 Vanderbilt Avenue New York, New York 10017 for the East European Countries, China, Northern Korea, Cuba, Vietnam and Mongolia SNTL Publishers of Technical Literature, Prague for all remaining areas ELSEVIER SCIENTIFIC PUBLISHING COMPANY Molenwerf 1, P. O. Box 211 1000 AE Amsterdam, The Netherlands Library of Congress Cataloging in Publication Data Hobst, Leos.· Anchoring in rock and soil. (Developments in geotechnical engineering ; 33) Translation of; Kotvenido hornin. Rev. ed. of: Anchoring in rock. 1977· Bibliography: p. Includes index. 1. Anchorage (Structural engineering) 2. Rock bolts· I. Zajic, Josef. II. Title. III. Series. TA772.H613 1982 62fcM5 82-871*8 ISBN' 0-1^-99689-3 MCR2 ISBN 0-444-99689-3 (Vol. 33) ISBN 0-444-41662-5 (Series) With 525 illustrations and 28 tables Translation by Ing. Prokop Maxa, Translation Editor Mark Cowan © 1983 Dr. Ing. Leo§ Hobst and Ing. Josef Zajic CSc Printed in Czechoslovakia PREFACE TO THE SECOND ENGLISH EDITION There is a growing tendency in the construction industry to exploit the ground as a means of taking up the tensile forces produced by structures, and to consolidate the damaged parts of rock masses or establish an effective support for them by introducing prestressing. Rock and soil consolidation is most effectively realized by means of prestressed reinforcements which are placed into boreholes in the ground and which connect the structure, or the superficial parts of the rock or soil, with the deeper mass. This efficient construction method is usually referred to as anchoring into rock and soil, or the tie-back method. The authors have played a part in the application of the anchoring method in Czechoslovakia from the very beginning, and decided more than ten years ago to attempt to evaluate and explain its problems, and to present their knowledge and experience in the first Czech edition of this book. The latter was much appreciated by its technical readership and in the years 1975 —1977 a supplemented second Czech edition was published together with an English translation for Elsevier who subsequently expressed interest in a completely revised edition. We cannot suppress a feeling of satisfaction that our efforts in summarizing the current knowledge on anchoring both from our own country and from abroad, were justified, thereby establishing a basis for the wider utilization of this knowledge. We are conscious of the fact that the success of our book has not been due to its literary merits, since the information it contains has been gathered from the minds of technical academic gentlemen. Success is due rather to the lack of published material summarizing the principles of anchoring, the advantages of its application in civil engineering, and the suitability of the individual anchoring techniques for various ground types and different anchored structures. The complexity of anchoring problems has been growing rapidly during the last decade and much new knowledge has been gained, although it has remained scattered throughout the literature. For this reason the book has had to be radically changed, and some chapters have been completely rewritten for this new edition. We have endeavoured to improve the text wherever this was desirable. It is our pleasant duty to extend our sincere thanks and gratitude on this occasion to our reviewers from all over the world for their stimulating comments on the previous edition, to all the experts and companies mentioned in the text for the use of their valuable specialized material, and of course to all our collaborators at the Research Institute of Civil Engineering and the national enterprise Stavebni geologie. Above all we thank Ing. Prokop Maxa for the translation of the book. Last but not least we thank our wives for their untiring support throughout our work. L. Hobst —J. Zajic Brno-Praha, June 1982 XIV RELATION OF SI UNITS TO EARLIER USED UNITS Length m (metre) = 1.09 yard = 3.28 feet = 39.37 inches cm (centimetre) = 0.39 inch mm (millimetre) = 0.47 line = 0.04 inch Area m2 (square metre) = 1.196 square yard = 10.76 square feet = 1,550 square inches cm2 (square centimetre) = 0.155 square inch = 0.00107 square foot mm2 (square millimetre) = 0.00155 square inch Volume m3 (cubic metre) = 1.308 cubic yard = 35.314 cubic feet cm3 (cubic centimetre) = 0.06 cubic inch Mass kg (kilogram) = 2.20 pounds = 35.274 ounces g (gram) 0.0353 ounces t (ton) = 2,204.6 pounds = 0.984 U.K. ton = 1.102 U.S. ton = 2.2 kips t/m3 (ton/cubic metre) = 103 kg/m3 = 62.427 pounds/cubic feet Force N (newton) = 0.1 kp (kilopond) = 3.527 ounces = 0.22 pound kN (kilonewton) = 100 kp (kilopond) == 220.5 pounds MN (meganewton) = 100 Mp (megapond) = 98.4 U.K. tonnes = 110.2 U.S. tonnes = 220 kips Pressure Pa (pascal) 1 N/m2 = 10"5 bar = 0.1 kp/m2 = (stress) 10"5 kp/cm2 = 0.0001 Mp/m2 = 10"5 atm = 0.000 142 pound/square inch (psi) MPa (megapascal) 1 MN/m2 = 1 N/mm2 = 10 bar = 10 kp/cm2 = 0.1 kp/mm2 = 100 Mp/m2 = 10 atm = 141. 935 pounds/square inch (psi) = 20.44 kips/square foot (ksf) Static Nm (newtonmetre) 1 joule (J) = 0.1 kpm = 0.72 lbft moment (work) kNm (kilonewtonmetre) = 0.1 Mpm = 723.2 pounds feet (lbft) Chapter 1 INTRODUCTION 1.1 TREATMENT OF THE SUBJECT The problems associated with anchoring into the ground are extensive and new ones arise all the time. We would like in this work to present a comprehensive summary of the development, principles, current state of technology and methods of application of anchoring. In order to facilitate the approach to these problems and ensure the reliability of information, particularly for those construction experts whose familiarity with the anchor- ing method is limited, we have divided the subject into three principal parts and 29 chapters. The chapters of the first, introductory, part A deal with the main principles of the anchoring method and its static analysis. Chapter 9 discusses the geotechnical properties of rocks and soils and their evaluation from the point of view of their capacity to take the tensile forces exerted by anchors. Chapter 10 explains the results of research concerning the behaviour of different types of the ground under the load of anchoring forces; it also includes the formulae derived for making approximate determinations of the anchor fixing depth both for individual anchors and grouped anchors, given the tensile forces and the required safety margins against failure. The second part of the book part B deals with anchoring technology. Mate- rials for the preparation of anchors, the main technological procedures for the fixing of anchors by different methods in different media, and the in- formation needed for the design of the anchor root are described. Other chapters of part B deal with the methods of fixing anchors to the surface of the structure, the methods of drilling and checking the anchoring bore- holes, and procedures and equipment used in the prestressing and testing of anchors together with long term monitoring of their function under various conditions. The third and largest part of the publication, C, presents theoretical data for anchorage design applied to various types of structures, and introduces some typical examples of both underground and surface constructions. The last chapter deals with the economics of anchoring by referring to several examples. 3 1.2 PRINCIPLES OF ANCHORING INTO THE GROUND Anchoring in rock or soil is a construction process in which prestressed components (termed anchors in this case) are embedded in the ground. The anchors are inserted into boreholes drilled in advance, and are fixed at the distal end. After fixing, the anchors are usually prestressed and their exposed upper ends are fixed to heads. The structure to which the anchor heads are attached, is either one which is dependent for its stability on the anchors, or it is merely a plate, slab, bar, grid or another structural element which distributes the stress induced by the anchor heads onto the wider surface of the rock or soil (Fig. 1-1). Anchoring in the ground fulfils three basic functions: — It establishes forces which act on the structure in a direction towards the point of contact with the rock or soil (Fig. 1-2). — It establishes a stress acting on the ground, or at least a reinforcement of the rock medium through which the anchor passes if non-prestressed anchorage is used (Fig. 1-3). — It establishes prestressing of the anchored structure itself, when the anchors pass through this structure. These functions are mutually complementary, or one or more of them may be inoperative, being inapplicable to the type of structure and anchoring method of a particular situation. Anchoring is always accompanied by the prestressing of the rock. In this process the ground is consolidated, strengthened, and its mechanical characteristics improved. This effect of anchoring is fully exploited when the walls of underground excavations, the rock faces of cuttings, the steep slopes of cuttings threatened by slumping, are secured; anchoring is utilized for the pre-consolidation of the underlying ground mass, or for controlling the deformation expected after completion of the construction, etc. Some- times, particularly when the faces of underground excavations are secured, the prestressing is substituted by a simple reinforcement with the use of anchors, without pre-induced stress; a partial stress in the rock then appears only when its superficial zones are loosened. This method is, however, technically and economically less expedient. The prestress introduced into a structure by the anchors may incorporate the otherwise occurring tensile stresses of the structure; such stresses appear, for example, within the masonry of gravity dams on the upstream face under hydrostatic load, etc. The establishment and utilization of a prestress by this means in masonry is not usually the main reason for the application of anchorage. Nevertheless these considerations must be analysed in every situation of an anchored structure, if not to exploit its contribution to prestressing, then at least to prevent possible damage and failure proper ^ -ι 1 S g n utis distrib— sill d-3 oas, lb on sla b) — ucture, cture, 2 ed strd stru Fig. 1-1. Fixing of anchor heads a) on the surface of the anchorstructural elements, 1 — anchore4 — grid, 5 — anchors Fig. 1-2. Schematic representation of the Fig. 1-3. Schematic drawing of the principle of anchoring a dam into bedrock stabilization of a rock face with / — anchor head, 2 — tendon, 3 — anchor prestressed anchors root, 4 — anchored structure 1 — anchor roots, 2 — anchor heads, 3 — prestressed rock by siting of the anchors on the structure and correct location of the load centre of the anchoring forces. The most efficient, most widely used technique is a system of anchorage in which forces are set up acting to lock together the structure with the rock. (see Fig. 1-2.) With such an arrangement the rock is exploited to greater effect and takes on the function of a proper construction material. The prestressed anchors create forces of known direction and magnitude which contribute to the stability of the superficial structure and tie together the entire complex consisting of the structure and the co-operating rock medium. The rock in which the structure is anchored takes the burden of the tensile and shear forces which arise from the structure and its load (or from natural changes in the superficial relief) more efficiently and to greater depths than occurs in the case of structures which are not anchored. On the other hand, a com- pressive force acting towards the plane of contact with the rock also appears in the structure, this force depending on the weight of the structure, or the pressure of a supporting brace or strut as the case may be. The structural complex created in this way is qualitatively superior, and exhibits mechanical characteristics which make it more capable of fulfilling its function at a lower capital cost. Anchorage, as a means of locking together the structure with the ground mass, makes it possible to choose with comparative ease on the basis of the static