ДСТУ EN 15512:2015 Системи складські стаціонарні сталеві. Збірно-розбірні палетні стелажні системи. Принципи проектування конструкцій (EN 15512:2009, ІDT)
ПІДТВЕРДЖУВАЛЬНЕ ПОВІДОМЛЕННЯ
Державне підприємство
«Український науково-дослідний і навчальний центр
проблем стандартизації, сертифікації та якості»
(
(ДП «УкрНДНЦ»))
Наказ від 03.08.2015 № 87
EN 15512:2009
Steel static storage systems - Adjustable pallet racking systems
- Principles for structural design
прийнято як національний стандарт
методом «підтвердження» за позначенням
ДСТУ EN 15512:2015
(EN 15512:2009, IDT)
Системи складські стаціонарні сталеві. Збірно-розбірні палетні стелажні системи.
Принципи проектування конструкцій
З наданням чинності від 2015–11–01
Contents
Foreword
Introduction
1 Scope
2 Normative references
3 Terms and definitions
4 Symbols
5 Basis of design
5.1 Requirements
5.1.1 Basic requirements
5.1.2 Un-braced racking systems
5.1.3 Braced racking systems
5.1.4 Design working life
5.1.5 Floor tolerances and deformations
5.2 Methods of design
5.2.1 General
5.2.2 Ultimate limit state
5.2.3 Serviceability limit state
5.3 Imperfections
5.3.1 General
5.3.2 Sway frame imperfections in un-braced systems
5.3.3 Bracing system imperfections
5.3.4 Imperfections in racks partially braced in the down-aisle direction
5.3.5 Member imperfections
6 Actions and combinations of actions
6.1 General
6.2 Permanent actions
6.2.1 General
6.2.2 Weights of materials and construction
6.3 Variable actions
6.3.1 General
6.3.2 Unit loads to be stored
6.3.3 Vertical placement loads
6.3.4 Horizontal placement loads
6.3.5 Effects of rack-guided equipment
6.3.6 Floor and walkway loads (see also EN 1991-1-1)
6.3.7 Actions arising from installation
6.4 Actions due to impact (accidental loads)
6.4.1 General
6.4.2 Accidental vertical actions
6.4.3 Accidental horizontal load
6.5 Wind loads
6.6 Snow loads
6.7 Seismic actions
7 Partial factors and combination rules
7.1 General
7.2 Combinations of actions for the ultimate limit state
7.3 Combination of actions for serviceability limit states
7.4 Load factors
7.5 Material factors
7.6 Stability against overturning
7.7 Racks braced against the building structure
8 Steel
8.1 General
8.1.1 Preliminary considerations
8.1.2 Material properties
8.1.3 Design values of material coefficients (general mechanical properties)
8.1.4 Steels with no guaranteed mechanical properties
8.1.5 Untested steels
8.2 Average yield strength of sections
8.3 Special selection of production material
8.4 Fracture toughness
8.5 Dimensional tolerances
8.5.1 General
8.5.2 Thickness of material
8.5.3 Tolerances on thickness
8.5.4 Width and depth of a cold-formed section
8.5.5 Member straightness
8.5.6 Twist
8.5.7 Tolerances with regard to design and assembly
8.6 Bracing eccentricities
8.7 Eccentricities between beams and uprights
8.8 Requirements for beam connector locks
8.9 Durability
9 Structural analysis
9.1 Structural modelling for analysis and basic assumption
9.2 Calculation of section properties
9.2.1 General
9.2.2 Effect of corner radii
9.2.3 Effect of perforations
9.2.4 Effect of cross-section distortion
9.2.5 Effect of local buckling
9.3 Beams
9.3.1 General
9.3.2 Moment of resistance of members not subject to lateral-torsional buckling
9.4 Design of beams
9.4.1 General
9.4.2 Loads on beams
9.4.3 Design bending moments for beams
9.4.4 Design shear force for beams
9.4.5 Deflection of beams
9.4.6 Beams as tie beams in braced pallet racks
9.4.7 Design resistance with respect to web crippling
9.4.8 Design resistance with respect to shear forces
9.4.9 Combined shear force, axial force and bending moment
9.4.10 Combined bending moment and web crippling
9.5 Design of beam end connectors
9.5.1 General
9.5.2 Design bending moments in beam end connectors
9.5.3 Design shear force for beam end connectors
9.5.4 Design shear force and bending moment for beam end connectors
9.6 Beams subject to bending and torsion
9.6.1 General
9.6.2 Lateral torsional buckling of beams
9.7 Compression, tension and bending in members
9.7.1 Non-perforated compression members
9.7.2 Perforated compression members
9.7.3 Cross sectional verification
9.7.4 Design strength with respect to flexural buckling
9.7.5 Torsional and flexural-torsional buckling
9.7.6 Combined bending and axial loading
9.8 Design of splices
9.9 Design of base plates
9.9.1 General
9.9.2 Effective area A bas for base plates
9.10 Floor materials
9.10.1 Concrete floors
9.10.2 Bituminous floors
9.10.3 Other floor materials
9.10.4 Design of anchorages
9.11 Design of run spacers
10 Global analysis of beam pallet racks
10.1 General considerations
10.1.1 General
10.1.2 Two dimensional analysis
10.1.3 Advanced three-dimensional analysis
10.2 Design procedure
10.2.1 Actions
10.2.2 Procedure
10.2.3 Analysis of braced and un-braced racks in the down-aisle direction
10.2.4 Moment-rotation characteristics of beam end connectors
10.2.5 Moment-rotation characteristics of the connection to the floor
10.3 Analysis of braced and un-braced racks in the cross-aisle direction
10.3.1 General
10.3.2 Out of plane stability
10.3.3 Frame classification
10.4 Methods of global analysis
10.5 Simplified methods of analysis for stability in the cross-aisle direction
10.6 Design of uprights
10.6.1 General
10.6.2 Design axial forces and bending moments
11 Serviceability limit states
11.1 General
11.2 Serviceability limit states for racking
12 Marking and labelling
12.1 Identification of performance of rack installations
13 Test methods and evaluation of results
13.1 General
13.2 Requirements for tests
13.2.1 Equipment
13.2.2 Support conditions
13.2.3 Application of the load
13.2.4 Increments of the test load
13.2.5 Assembly of test specimens
13.2.6 Test reports
13.3 Interpretation of test results
13.3.1 Definition of failure load
13.3.2 Corrections to test results
13.3.3 Derivation of characteristic values
13.3.4 Characteristic values for a family of tests
13.3.5 Corrections to failure loads or moments
Annex A (normative) Testing
A.1 Materials tests
A.1.1 Tensile test
A.1.2 Bend tests
A.2 Tests on components and connections
A.2.1 Stub column compression test
A.2.2 Compression tests on uprights - Checks for the effects of distortional buckling
A.2.3 Compression tests on uprights - Determination of buckling curves
A.2.4 Bending tests on beam end connectors
A.2.5 Looseness tests on beam end connectors
A.2.6 Shear tests on beam end connectors and connector locks
A.2.7 Tests on floor connections
A.2.8 Tests for the shear stiffness of upright frames
A.2.9 Bending tests on upright sections
A.2.10 Bending tests on beams
A.2.11 Tests on upright splices
Annex B (informative) Amplified sway method for down-aisle stability analysis
B.1 General
B.2 Linear elastic analysis
B.3 Elastic critical value
B.4 Amplification factor
Annex C (informative) Approximate equations for the design of a regular storage rack in the down-aisle direction
C.2 Additional bending moments due to pattern loading
C.3 Design Moments
C.4 Design loads in outer columns
Annex D (informative) Background to the acceptance of materials of low f u /f y ratio (cold reduced steel)
Annex F (informative) Equivalent beam loads
Annex G (informative) Simplified method for cross-aisle stability analysis in circumstances where there is uniform distribution of compartment loads over the height of the upright frame
G.1 General
G.2 Global buckling of upright frames.
G.3 Shear stiffness of upright frame
G.4 Amplification factor β
Annex H (informative) Factory production control (FPC)
H.1 General
H.2 Frequency of tests
H.3 Bending tests on beam end connectors
H.4 Bend tests
Annex I (informative) A–deviations
I.1 Dutch national legislative deviations
I.2 German national legislative deviations
Bibliography
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