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Design of aluminium structures Eurocode 8 - prEN 1998-4_ 2003 [Silos, tanks and pipelines] This series of Designers'' Guides to the Eurocodes provides comprehensive guidance in the form of design aids, indications for the most convenient design procedures and worked examples. The books also include background information to aid the designer in understanding the reasoning behind and the objectives of the codes. All of the individual guides work in conjunction with the Designers'' Guide to Eurocode: Basis of Structural Design. EN 1990. Aluminium is not as widely used for structural applications as it could be, partly as a result of misconceptions about material strength and durability but largely because engineers and designers have not been taught how to use it - additional specific design checks are needed. A material with unique properties that need to be exploited and worked with, aluminium has many benefits and, when used correctly, the results are light, durable, cost effective structures. EN 1999, Eurocode 9: Design of aluminium structures, details the requirements for resistance, serviceability, durability and fire resistance in the design of buildings and other civil engineering and structural works in aluminium. This guide provides the user with guidance on the interpretation and use of Part 1-1: General structural rules and Part 1-4: Cold-formed structural sheeting of EN 1999, covering material selection and all main structural elements and joints. Designers'' Guide to Eurocode 9: Design of Aluminium Structures
Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X prEN 1998-4 : 2003 EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM December 2003 UDC Descriptors: Doc CEN/TC250/SC8/N387 English version Eurocode : Design of structures for earthquake resistance Part 4: Silos, tanks and pipelines Calcul des structures pour leur résistance Auslegung aux séismes Erdbeben von Partie : Silos, réservoirs et réseaux de Teil : Silos, tuyauteries Rohrleitungen Bauwerken gegen Tankbauwerke und Draft No CEN European Committee for Standardisation Comité Européen de Normalisation Europäisches Komitee für Normung Central Secretariat: rue de Stassart 36, B-1050 Brussels © 2003 Copyright reserved to all CEN members EUROPEAN PRESTANDARD Ref No EN 1998-4 : 2003 (E) prEN 1998-4 Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X PRÉNORME EUROPÉENNE EUROPÄISCHE VORNORM Doc CEN/TC250/SC8/N322 English version Eurocode 8: Design of structures for earthquake resistance Part 4: Silos, tanks and pipelines DRAFT No (Stage 32) June 2002 CEN European Committee for Standardization Comité Européen de Normalisation Europäisches Komitee für Normung Central Secretariat: rue de Stassart 36, B1050 Brussels Draft 2(Stage 32) Draft December 2003June 2002 CEN 2002 Copyright reserved to all CEN members Ref.No ENV 1998-4 Page prEN 1998-4:200X Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X Contents GENERAL .1 1.1 SCOPE .1 1.2 NORMATIVE REFERENCES .11 1.2.1 General reference standards 1.3 ASSUMPTIONS 1.4 DISTINCTION BETWEEN PRINCIPLES AND APPLICATIONS RULES 1.5 TERMS AND DEFINITIONS 1.5.1 Terms common to all Eurocodes 1.5.2 Additional terms used in the present standard .2 1.6 SYMBOLS 1.7 S.I UNITS .22 GENERAL RULES 33 2.1 SAFETY REQUIREMENTS 33 2.1.1 General .33 2.1.2 Damage limitation state 33 2.1.3 Ultimate limit state .33 2.1.4 Reliability differentiation 44 2.1.5 System versus element reliability 55 2.1.6 Conceptual design 55 2.2 SEISMIC ACTION 66 2.3 ANALYSIS .77 2.3.1 Methods of analysis 77 2.3.2 Behaviour factors .88 2.3.3 Damping .88 2.3.3.1 2.3.3.2 2.3.3.3 Structural damping 88 Contents damping 88 Foundation damping 99 2.3.4 Interaction with the soil 99 2.3.5 Weighted damping 99 2.4 SAFETY VERIFICATIONS 99 2.4.1 General .99 2.4.2 Combinations of seismic action with other actions 99 SPECIFIC RULES FOR SILOS .1111 3.1 PROPERTIES OF STORED SOLIDS AND DYNAMIC PRESSURES .1111 3.2 COMBINATION OF GROUND MOTION COMPONENTS 1111 3.3 ANALYSIS 1111 3.4 BEHAVIOUR FACTORS .1313 3.5 VERIFICATIONS 1414 3.5.1 Damage limitation state 1414 3.5.2 Ultimate limit state 1414 3.5.2.1 3.5.2.2 3.5.2.3 3.5.2.4 Global stability 1414 Shell 1515 Anchors 1515 Foundations 1515 SPECIFIC RULES FOR TANKS .1616 4.1 COMPLIANCE CRITERIA .1616 4.1.1 General 1616 4.1.2 Damage limitation state 1616 4.1.3 Ultimate limit state 1616 4.2 COMBINATION OF GROUND MOTION COMPONENTS 1717 4.3 METHODS OF ANALYSIS 1717 4.3.1 General 1717 4.3.2 Behaviour factors 1717 4.3.3 Hydrodynamic effects .1818 4.4 VERIFICATIONS 1818 Draft 2(Stage 32) Draft December 2003June 2002 4.4.1 Damage limitation state 1818 4.4.1.1 4.4.1.2 4.4.2 Page prEN 1998-4:200X Shell 1818 Piping 1919 Ultimate limit state 1919 4.4.2.1 4.4.2.2 4.4.2.3 4.4.2.4 4.4.2.5 Stability 1919 Shell 1919 Piping 1919 Anchorages 1919 Foundations 2020 4.5 COMPLEMENTARY MEASURES 2020 4.5.1 Bunding 2020 4.5.2 Sloshing 2020 4.5.3 Piping interaction 2020 SPECIFIC RULES FOR ABOVE-GROUND PIPELINES 2121 5.1 GENERAL 2121 5.2 SAFETY REQUIREMENTS 2121 5.2.1 Damage limitation state 2121 5.2.2 Ultimate limit state 2222 5.2.3 Reliability differentiation 2222 5.3 SEISMIC ACTION 2222 5.3.1 General 2222 5.3.2 Earthquake vibrations 2323 5.3.3 Differential movement 2323 5.4 METHODS OF ANALYSIS 2323 5.4.1 Modelling 2323 5.4.2 Analysis 2323 5.4.3 Behaviour factors 2424 5.5 VERIFICATIONS 2424 SPECIFIC RULES FOR BURIED PIPELINES 2626 6.1 GENERAL 2626 6.2 SAFETY REQUIREMENTS 2626 6.2.1 Damage limitation state 2626 6.2.2 Ultimate limit state 2626 6.2.3 Reliability differentiation 2727 6.3 SEISMIC ACTION 2727 6.3.1 General 2727 6.3.2 Earthquake vibrations 2828 6.3.3 Modelling of seismic waves 2828 6.3.4 Permanent soil movements .2828 6.4 METHODS OF ANALYSIS (WAVE PASSAGE) 2828 6.5 VERIFICATIONS 2828 6.5.1 General 2828 6.5.1.1 6.5.1.2 6.6 Buried pipelines on stable soil 2929 Buried pipelines under differential ground movements (welded steel pipes) ( 2929 DESIGN MEASURES FOR FAULT CROSSINGS .2929 ANNEX A (INFORMATIVE) SEISMIC ANALYSIS OF SILOS 3131 ANNEX B (INFORMATIVE) SEISMIC ANALYSIS PROCEDURES FOR TANKS 3737 ANNEX C (INFORMATIVE) BURIED PIPELINES .6767 Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X Foreword This document (EN 1998-4:200X) has been prepared by Technical Committee CEN/TC 250 "Structural Eurocodes", the secretariat of which is held by BSI This European Standard shall be given the status of a national standard, either by publication of an identical text or by endorsement, at the latest by MM-200Y, and conflicting national standards shall be withdrawn at the latest by MM-20YY This document supersedes ENV 1998-4:1997 CEN/TC 250 is responsible for all Structural Eurocodes Background of the Eurocode programme In 1975, the Commission of the European Community decided on an action programme in the field of construction, based on article 95 of the Treaty The objective of the programme was the elimination of technical obstacles to trade and the harmonisation of technical specifications Within this action programme, the Commission took the initiative to establish a set of harmonised technical rules for the design of construction works which, in a first stage, would serve as an alternative to the national rules in force in the Member States and, ultimately, would replace them For fifteen years, the Commission, with the help of a Steering Committee with Representatives of Member States, conducted the development of the Eurocodes programme, which led to the first generation of European codes in the 1980’s In 1989, the Commission and the Member States of the EU and EFTA decided, on the basis of an agreement1 between the Commission and CEN, to transfer the preparation and the publication of the Eurocodes to CEN through a series of Mandates, in order to provide them with a future status of European Standard (EN) This links de facto the Eurocodes with the provisions of all the Council’s Directives and/or Commission’s Decisions dealing with European standards (e.g the Council Directive 89/106/EEC on construction products - CPD - and Council Directives 93/37/EEC, 92/50/EEC and 89/440/EEC on public works and services and equivalent EFTA Directives initiated in pursuit of setting up the internal market) The Structural Eurocode programme comprises the following standards generally consisting of a number of Parts: EN 1990 Eurocode: Basis of structural design EN 1991 Eurocode 1: Actions on structures EN 1992 Eurocode 2: Design of concrete structures Agreement between the Commission of the European Communities and the European Committee for Standardisation (CEN) concerning the work on EUROCODES for the design of building and civil engineering works (BC/CEN/03/89) Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X EN 1993 Eurocode 3: Design of steel structures EN 1994 Eurocode 4: Design of composite steel and concrete structures EN 1995 Eurocode 5: Design of timber structures EN 1996 Eurocode 6: Design of masonry structures EN 1997 Eurocode 7: Geotechnical design EN 1998 Eurocode 8: Design of structures for earthquake resistance EN 1999 Eurocode 9: Design of aluminium structures Eurocode standards recognise the responsibility of regulatory authorities in each Member State and have safeguarded their right to determine values related to regulatory safety matters at national level where these continue to vary from State to State Status and field of application of Eurocodes The Member States of the EU and EFTA recognise that Eurocodes serve as reference documents for the following purposes: – as a means to prove compliance of building and civil engineering works with the essential requirements of Council Directive 89/106/EEC, particularly Essential Requirement N°1 - Mechanical resistance and stability - and Essential Requirement N°2 - Safety in case of fire; – as a basis for specifying contracts for construction works and related engineering services; – as a framework for drawing up harmonised technical specifications for construction products (ENs and ETAs) The Eurocodes, as far as they concern the construction works themselves, have a direct relationship with the Interpretative Documents2 referred to in Article 12 of the CPD, although they are of a different nature from harmonised product standards3 Therefore, technical aspects arising from the Eurocodes work need to be adequately considered by CEN Technical Committees and/or EOTA Working Groups working on product According to Art 3.3 of the CPD, the essential requirements (ERs) shall be given concrete form in interpretative documents for the creation of the necessary links between the essential requirements and the mandates for hENs and ETAGs/ETAs According to Art 12 of the CPD the interpretative documents shall : a) give concrete form to the essential requirements by harmonising the terminology and the technical bases and indicating classes or levels for each requirement where necessary ; b) indicate methods of correlating these classes or levels of requirement with the technical specifications, e.g methods of calculation and of proof, technical rules for project design, etc ; c) serve as a reference for the establishment of harmonised standards and guidelines for European technical approvals The Eurocodes, de facto, play a similar role in the field of the ER and a part of ER Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X standards with a view to achieving a full compatibility of these technical specifications with the Eurocodes The Eurocode standards provide common structural design rules for everyday use for the design of whole structures and component products of both a traditional and an innovative nature Unusual forms of construction or design conditions are not specifically covered and additional expert consideration will be required by the designer in such cases National Standards implementing Eurocodes The National Standards implementing Eurocodes will comprise the full text of the Eurocode (including any annexes), as published by CEN, which may be preceded by a National title page and National foreword, and may be followed by a National annex (informative) The National annex may only contain information on those parameters which are left open in the Eurocode for national choice, known as Nationally Determined Parameters, to be used for the design of buildings and civil engineering works to be constructed in the country concerned, i.e : – values and/or classes where alternatives are given in the Eurocode, – values to be used where a symbol only is given in the Eurocode, – country specific data (geographical, climatic, etc.), e.g snow map, – the procedure to be used where alternative procedures are given in the Eurocode It may also contain – decisions on the application of informative annexes, – references to non-contradictory complementary information to assist the user to apply the Eurocode Links between Eurocodes and harmonised technical specifications (ENs and ETAs) for products There is a need for consistency between the harmonised technical specifications for construction products and the technical rules for works4 Furthermore, all the information accompanying the CE Marking of the construction products which refer to Eurocodes shall clearly mention which Nationally Determined Parameters have been taken into account Additional information specific to EN 1998-4 See Art.3.3 and Art.12 of the CPD, as well as clauses 4.2, 4.3.1, 4.3.2 and 5.2 of ID Draft 2(Stage 32) Draft December 2003June 2002 Page prEN 1998-4:200X The scope of EN 1998 is defined in 1.1.1 of EN 1998-1:2004 The scope of this Part of EN 1998 is defined in 1.1 Additional Parts of Eurocode are listed in EN 1998-1:2004, 1.1.3 EN 1998-4:200X is intended for use by: – clients (e.g for the formulation of their specific requirements on reliability levels and durability) ; – designers and constructors ; – relevant authorities For the design of structures in seismic regions the provisions of this European Standard are to be applied in addition to the provisions of the other relevant parts of Eurocode and the other relevant Eurocodes In particular, the provisions of this European Standard complement those of EN 1991-4, EN 1992-3, EN 1993-4-1, EN 1993-4-2 and EN 19934-3, which not cover the special requirements of seismic design National annex for EN 1998-4 This standard gives alternative procedures, values and recommendations for classes with notes indicating where national choices may be made Therefore the National Standard implementing EN 1998-4 should have a National Annex containing all Nationally Determined Parameters to be used for the design of buildings and civil engineering works to be constructed in the relevant country National choice is allowed in EN 1998-4:200X through clauses: Reference Item Draft 2(Stage 32) Draft December 2003June 2002 1.1 Page prEN 1998-4:200X GENERAL Scope (1)P This standard aims at providing principles and application rules for the seismic design of the structural aspects of facilities composed of above-ground and buried pipeline systems and of storage tanks of different types and uses, as well as for independent items, such as for example single water towers serving a specific purpose or groups of silos enclosing granular materials, etc This standard may also be used as a basis for evaluating the resistance of existing facilities and to assess any required strengthening (2) P This standard includes the additional criteria and rules required for the seismic design of these structures without restrictions on their size, structural types and other functional characteristics For some types of tanks and silos, however, it also provides detailed methods of assessment and verification rules (3) P This standard may not be complete for those facilities associated with large risks to the population or the environment, for which additional requirements shall be established by the competent authorities This standard is also not complete for those construction works which have uncommon structural elements and which require special measures to be taken and special studies to be performed to ensure earthquake protection In those two cases the present standard gives general principles but not detailed application rules (4) The nature of lifeline systems which often characterises the facilities covered by this standard requires concepts, models and methods that may differ substantially from those in current use for more common structural types Furthermore, the response and the stability of silos and tanks subjected to strong seismic actions may involve rather complex interaction phenomena between of soil-structure and stored material (either -fluid or granular)interaction, not easily amenable to simplified design procedures Equally challenging may prove to be the design of a pipeline system through areas with poor and possibly unstable soils For the reasons given above, the organisation of this standard is to some extent different from that of companion Parts of EN 1998 This standard is, in general, restricted to basic principles and methodological approaches NOTE Detailed analysis procedures going beyond basic principles and methodological approaches are given in Annexes A, B and C for a number of typical situations (5) P For the formulation of the general requirements as well as for their its implementation, a distinction can shall be made between independent structures and redundant systems, via the choice of importance factors and/or through the definition of adapted specific verification criteria (6) P A structure maycan be considered as independent when its structural and functional behaviour during and after a seismic event is not influenced by that of other structures, and if the consequences of its failure relate only to the functions demanded from it Draft 2(Stage 32) Draft December 2003June 2002 Page 60 prEN 1998-4:200X The first mode sloshing frequencies for tanks of various shapes, including horizontal circular cylinders, with motion along and transverse to the axis, are shown in Fig.Figure B.9 B.6 Elevated tanks Elevated tanks can have supporting structures of different types, from simple cylindrical towers to frame or truss-like structures For the purpose of the analysis, the presence of the liquid in the supported tank can be accounted for considering two masses: an impulsive mass mi located at a height h’i above the tank bottom (eq (B.4) and (B.6), respectively), and a mass mc1 located at a height hc1 (eq (B.12) and (B.14), respectively) The mass mi is rigidly connected to the tank walls, while the mass mc1 is connected to the walls through a spring of stiffness: Kc1 = ω2c1 mc1, where ωc1 is given by eq (B.9) The mass of the tank is included in the structural model which describes also the supporting structure The response of the system can be evaluated using standard modal analysis and response spectra methods In the simplest possible case, the global model has only two degrees-of-freedom, corresponding to the masses mi and mc1 (the mass of the tank and an appropriate portion of the mass of the support has to be added to mi) The mass (mi + ∆m) is connected to the ground by a spring representing the stiffness of the support In some cases, the rotational inertia of the mass (mi + ∆m), and the corresponding additional degree of freedom, need also to be considered In the relatively common case where the shape of the elevated tank is a truncated inverted cone (or close to it), an equivalent cylinder can be considered, having the same volume of liquid as the real tank, and a diameter equal to that of the cone at the level of the liquid B.7 Soil-structure interaction effects For tanks founded on relatively deformable soils, the resulting base motion can be significantly different from the free-field motion, and it includes generally a rocking component, in addition to a modified translational component Accurate solutions for the interaction problem between tank-fluid and soil systems have been developed only recently for the case of tanks with rigid foundation on homogeneous soil: see ref [14], [15], [16] The solution procedures are based on the sub-structuring approach, whereby the response of the deformable tank and of the soil beneath the foundation are first expressed separately for an excitation consisting of a horizontal and a rocking motion: equilibrium and compatibility conditions imposed at the interface yield a set of two equations on the unknown ground displacement components Analyses performed on tanks of various geometries confirm what was known from previous studies on building systems Increasing the flexibility of the supporting medium lengthens the period of the tank-fluid system and reduces the peak of the response (for the same input) due to an increase of the total damping For a given soil flexibility, the increase in the fundamental period is more pronounced for tall, slender tanks, because the contribution of the rocking component is greater for these structures than for short, broad tanks The reduction of the peak response, however, is in general less significant for tall tanks, since the damping associated Draft 2(Stage 32) Draft December 2003June 2002 Page 61 prEN 1998-4:200X with rocking is smaller than the damping associated with horizontal translation Although the method in ref [15] would be easily implemented in a computer code, simpler procedures are desirable for design purposes One such procedure has been proposed for buildings already several years ago, see ref [13], and consists of a modification (increase) of the fundamental period and of the damping of the structure, considered to rest on a rigid soil and subjected to the free-field motion This procedure has been extended to tanks, see refs [15] and [16], and more specifically, to the impulsive (rigid and flexible) components of the response The convective periods and pressures are assumed not to be affected by soil-structure interaction The recent study in ref [15] confirms the good approximation that can be obtained through the use of an equivalent simple oscillator with parameters adjusted to match frequency and peak response of the actual system The properties of the replacement oscillator are given in ref [15] in the form of graphs, as functions of the ratio H/R and for fixed values of the other parameters: wall thickness ratio s/R, initial damping, etc These graphs can be effectively used whenever applicable Alternatively, the less approximate procedure of ref [2] and [10], as summarised below, can still be adopted Since the hydrodynamic effects considered in B.2 to B.5 and, specifically, the impulsive rigid and impulsive flexible pressure contributions, are mathematically equivalent to a single degree-of-freedom system, and they are uncoupled from each other, the procedure operates by simply changing separately their frequency and damping factors In particular, for the rigid impulsive pressure components, whose variation with time is given by the free-field horizontal: Ag(t), and vertical: Aν(t) accelerations, inclusion of soil-structure interaction effects involves replacing the time-histories above with the response acceleration functions of a single degree of freedom oscillator having frequency and damping factors values as specified below Modified natural periods – "rigid tank" impulsive effect, horizontal 1/ m + mo mi hi'2 + Ti = 2π i kθ α θ kxα x * – "deformable tank" impulsive effect, horizontal k h2 k Tf* = Tf 1 + f + 1 + x f k x α x kθ α θ – (B.51) "rigid tank", vertical (B.52) Draft 2(Stage 32) Draft December 2003June 2002 Page 62 prEN 1998-4:200X 1/ m T = 2π tot kvα v * vr – (B.53) "deformable tank”, vertical 1/ k T = Tvd 1 + kvα v * vd (B.54) where: mi , h’i mass and height of the impulsive component mo mass of the foundation kf stiffness associated to the "deformable tank" = 4π mf Tf2 mtot total mass of the filled tank, including foundation k1 ml , with mi = mass of the contained liquid Tv2d = 4π where: kx,kθ,kν horizontal, rocking and vertical stiffness of the foundation αx,αθ,αν frequency dependent factors which convert the static stiffnesses into the corresponding dynamic ones Modified damping values The general expression for the effective damping ratio of the tank-foundation system is: ξ = ξs + (T ξm * /T ) (B.55) where: ξs radiation damping in the soil ξm material damping in the tank Both ξs and ξm depend on the specific oscillation mode In particular for ξs one has: – for the horizontal impulsive “rigid tank” mode ξ s = 2π a β x k x hi'2 β θ + Ti * α x kθ α θ (B.56) Draft 2(Stage 32) Draft December 2003June 2002 – for the horizontal impulsive “deformable tank” mode ξs = – Page 63 prEN 1998-4:200X 2π mf k x Tf*2 β k h2 β a x + x f θ kθ α θ αx (B.57) for the vertical “rigid tank” mode ξ s = 2π a βv Tv*r α v (B.58) where: a dimensionless frequency function = β x , β v , βθ 2π R (Vs = shear wave velocity of the soil) Vs T frequency-dependent factors providing radiation damping values for horizontal vertical and rocking motions Expressions for the factors α x , α θ , α v and β x , β θ , β v can be found for example in ref.[4] B.8 Unanchored tanks Tanks are often built with the walls not anchored to the foundation, for reasons of economy In case of earthquake, if the overturning moment due to the hydrodynamic forces is larger than the stabilizing one some uplift occurs It is difficult to avoid in this case plastic deformations in the tank, at least in the base plate Leakage of the liquid, however, can be prevented by proper design The mechanism of tank uplift is obviously complex and substantcially sensitive to several parameters, both from the point of view of tank response and of the subsequent stress analysis In most cases, the effects of the uplift, and of the accompanying rocking motion, on the magnitude and the distribution of the pressures is disregarded, and the pressures calculated for an anchored tank are used This is believed to be in many a conservative approach, due to the fact that rocking adds flexibility to the tank-fluid system, and hence shifts the period into a range of lesser amplification This approach is accepted in ref [5] The only approximate design procedure elaborated thus far which accounts for the dynamic nature of the problem is presented in ref [3], and can be used if deemed appropriate For the purpose of the present Annex a conceptual outline of the procedure in ref [3] is adequate – The sloshing and the rigid impulsive pressure components are assumed to remain unaffected by the rocking motion – The flexible impulsive component is treated using expressions analogous to eq (B.18) to (B.28), but on the basis of a first mode shape which includes, in addition to the deformation of the shell, the uplift of the base Modified values of the mass mf and of its Draft 2(Stage 32) Draft December 2003June 2002 Page 64 prEN 1998-4:200X height hf are obtained, as functions, as before, of the ratio H/R; of course these modified values depend on the amount of uplift, but this dependence is found numerically to be weak so that average values can be used – For what concerns the dynamic response, the objective is to find the fundamental period of a system made up of a deformable tank-fluid sub-system, linked to the ground by means of vertical springs characterized by a non-linear force-uplift relationship – The non-linearity of the base springs is treated in an "equivalent" linear way by assuming their average stiffness for a vertical deformation going from zero to the maximum value reached during the response Based on extensive Finite Element analyses on steel tanks typical of oil industry, results have been obtained in the form of graphs, which give the fundamental period of the whole system in the form: Tf = 2π R d max H F , g R R (B.59) where dmax is the maximum displacement at the level hf where the mass mf is located, and F(⋅) is an empirical function of the two nonadimensional parameters indicated The procedure then works iteratively as follows: – starting with the fixed-base value of the overturning moment, a value of dmax is obtained using a non-dimensional graph prepared for different H/R values; – based on this value, the period of the system is calculated from eq (B.59), and using the appropriate response spectrum, the impulsive flexible component of the response is obtained; – combining the latter response with the sloshing and the rigid-one, a new value of the total overturning moment is obtained, and so forth until convergence is achieved The limitation in the use of the procedure described is that available design charts refer to specific values of important parameters, as for ex the thickness ratio of the wall, the soil stiffness, the wall foundation type, etc., which are known to influence the response to a significant extent Once the hydrodynamic pressures are known, whether determined ignoring or considering occurrence of uplift, the following step of calculating the stresses in the critical regions of the tank is a matter of structural analysis, an area in which the designer must have a certain freedom in selecting the level of sophistication of the method he uses, under the condition that the less approximate ones must be clearly on the safe side For an uplifting tank, an accurate model would necessarily involve a Finite Element method with non-linear capabilities, a fact which is still out of common practice At the other extreme, rather crude methods, not requiring the use of computer, have been developed long ago, and they are still proposed in current design standards, as for ex in ref [10] These methods have been proven to be unconservative by experiments and by more refined analyses and, more generally, to be inadequate for accounting of all the variables entering the problem Draft 2(Stage 32) Draft December 2003June 2002 Page 65 prEN 1998-4:200X Simplified but comprehensive computer methods have been proposed recently in the literature, see for ex ref [7] and [9], and they will gradually replace the present ones The principal effect of uplift is to increase the compressive vertical stress in the shell, which is critical with regard to buckling-related types of failure At the opposite side of the wall where the compression is maximum, hoop compressive stresses are generated in the shell, due to the membrane action of the base plate These latter stresses, however, in combination with the other stress components, are not critical for the stability of the tank Finally, flexural yielding is accepted to take place in the base plate, and a check of the maximum tensile stress is appropriate Compressive axial stress in the wall due to uplift The increase of the vertical stress due to uplift (Nu) with respect to the stress in the anchored case (Na) can be estimated from Fig.Figure B.10, taken from ref [12] The ratio Nu/Na is given in Fig.Figure B.10 as function of the nonadimensional overturning moment: M/WH (W = total weight of the liquid) It is seen that for slender tanks the increase is very significant The values in Fig.Figure B.10 should be on the safe side, since they have been calculated (using static Finite Element analysis) assuming the underlying soil to be quite rigid (Winkler coefficient k=4000 N/cm3) which is an unfavourable situation for the considered effect Fig.Figure B.10: Ratio of maximum compressive axial membrane force for unanchored and anchored tanks versus overturning moment (from ref [12]) Shell uplift and uplifted length of the base plate From a parametric study with F.E models, performed on a number of tanks of commonly Draft 2(Stage 32) Draft December 2003June 2002 Page 66 prEN 1998-4:200X used geometry, the amount of uplift has been derived in ref [12], and it is given in Fig.Figure B.11 as a function of the overturning moment M/WH, for different values of the ratio H/R For estimating the radial membrane stresses in the plate, the length L of the uplifted part of the tank bottom is also necessary Results obtained from the parametric study mentioned above are shown in Fig.Figure B.12 The dependence of L on the uplift w is almost linear, the values of L being larger (for a given w) for squat tanks than for slender ones Fig.Figure B.11: Maximum uplift height versus overturning moment M/WH (from ref [12]) Radial membrane stresses in the base plate An estimate of the membrane stress σrb in the base plate due to uplift has been derived in ref [1]: ( ) 1/ 1 σ rb = E − ν R (1 − µ )2 t3 (B.60) where t is the thickness of the plate p is the hydrostatic pressure on the base µ = (R/L)/R, with L = uplifted part of the base Plastic rotation of the base plate A recommended practice is to design the bottom annular ring with a thickness less than the wall thickness, so as to avoid flexural yielding at the base of the wall Draft 2(Stage 32) Draft December 2003June 2002 Page 67 prEN 1998-4:200X Fig.Figure B.12: Length of the uplifted part as a function of the uplift (from ref [12]) The rotation of the plastic hinge in the tank base must be compatible with the available flexural ductility Assuming a maximum allowable steel strain of 0,05 and a length of the plastic hinge equal to t, the maximum allowable rotation is 0,05 θ = 2t = 0,20 radians t/2 (B.61) From Fig.Figure B.13 the rotation associated to an uplift w and a base separation of L is: 2w w θ = − L 2R which must be less than 0,20 radians (B.62) Draft 2(Stage 32) Draft December 2003June 2002 Page 68 prEN 1998-4:200X Fig.Figure B.13: Plastic rotation of base plate of uplifting tank (from ref [10]) B.9 Stability verifications for steel tanks Stability verifications have to be performed with respect to two possible failure modes a) Elastic buckling This form of buckling has been observed to occur in those parts of the shell where the thickness is reduced with respect to the thickness of the base, and the internal pressure (which has a stabilising effect) is also reduced with respect to the maximum value it attains at the base This verification should be carried out assuming the vertical component of the seismic excitation to give zero contribution to the internal pressure Denoting by σm the maximum vertical membrane stress, the following inequality shall be satisfied: σ σm ≤0,19 + 0,81 p σ c1 σ c1 (B 63) where σ c1 = 0,6 ⋅ E s R (B.64) (ideal critical buckling stress for cylinders loaded in axial compression) 2 p σo σ p = σ c1 1 − 1 − 1 − σ c1 p= 1/ pR