I.S. ENV 1994-2:1998
Superseded
A superseded Standard is one, which is fully replaced by another Standard, which is a new edition of the same Standard.
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EUROCODE 4: DESIGN OF COMPOSITE STEEL AND CONCRETE STRUCTURES - PART 2: COMPOSITE BRIDGES
Hardcopy , PDF
16-01-2006
English
01-01-1998
For Harmonized Standards, check the EU site to confirm that the Standard is cited in the Official Journal.
Only cited Standards give presumption of conformance to New Approach Directives/Regulations.
Dates of withdrawal of national standards are available from NSAI.
Foreword
1 General
1.1 Scope
1.1.2 Scope of ENV 1994-2:1997
1.2 Distinction between principles and application
rules
1.3 Assumptions
1.4 Definitions
1.4.2 Special terms used in this Part
1.4.3 Other definitions
1.5 S.I. units
1.6 Symbols used in Part 2
1.6.1 General
1.6.2 Latin upper case letters
1.6.3 Greek upper case letters
1.6.4 Latin lower case letters
1.6.5 Greek lower case letters
1.6.6 Subscripts
1.6.7 Use of subscripts
1.6.8 Conventions for member axes
1.7 Normative references
2 Basis of design
2.2 Definitions and classifications
2.2.1 Limit states and design situations
2.2.2 Actions
2.2.5 Load arrangements and load cases
2.3 Design requirements
2.3.1 General
2.3.2 Ultimate limit states, including fatigue
2.3.3 Partial safety factors for ultimate limit
states, including fatigue
2.3.4 Serviceability limit states
2.4 Durability
3 Materials
3.1 Concrete
3.1.1 General
3.1.2 Concrete strength classes
3.1.3 Shrinkage of concrete
3.1.4 Deformability of concrete - elastic theory
3.1.5 Deformability of concrete - other theories
3.1.6 Thermal expansion
3.2 Reinforcing steel
3.2.1 General
3.2.2 Types of steel
3.2.4 Modulus of longitudinal deformation
3.3 Structural steel
3.3.1 General and scope
3.3.2 Yield strength
3.3.5 Dimensional and mass tolerances
3.3.6 Fracture toughness
3.4 Profiled steel sheeting for composite slabs
3.5 Connecting devices
3.5.2 Shear connectors
3.6 Prestressing steel and devices
4 Ultimate limit states
4.1 Basis
4.1.1 General
4.2 Properties of cross-sections of beams
4.2.1 Effective section
4.2.2 Effective width of flanges with respect
to shear lag
4.2.3 Flexural stiffness
4.3 Classification of cross-sections of beams
4.3.1 General
4.3.2 Classification of steel flanges in
compression
4.3.3 Classification of steel webs
4.4 Resistances of cross-sections of beams
4.4.1 Bending moment
4.4.2 Vertical shear
4.4.3 Bending, axial force, and vertical shear
4.4.6 Flange-induced buckling of webs
4.5 Global analysis for bridge structures
4.5.1 General
4.5.3 Elastic analysis
4.5.4 Non-linear global analysis
4.6 Lateral-torsional buckling of composite beams
4.6.1 General
4.6.2 Lateral buckling of beams with cross-sections
in Class 1 or 2
4.6.3 Effects of transverse frames
4.7 Tension members in composite bridges
4.7.1 General
4.7.2 Concrete tension members
4.7.3 Composite tension members
4.8 Composite compression members
4.8.1 Scope
4.8.2 General method of design
4.8.3 Simplified method of design
4.11 Box girders
4.12 Fatigue
4.12.1 General
4.12.2 Fatigue loading and partial safety factors
4.12.3 Internal forces
4.12.4 Stresses and stress range delta sigma[E]
4.12.5 Fatigue resistance
4.12.6 Simplified assessment
5 Serviceability limit states
5.1 General
5.1.1 Scope
5.1.2 Classification of structures
5.1.3 Global analysis for serviceability limit
states
5.1.4 Calculation of stresses in cross sections
5.2 Limitation of stresses
5.3 Crack and decompression control
5.3.1 General
5.3.2 Minimum reinforcement
5.3.3 Control of cracking
5.4 Deformations
5.5 Vibration
6 Shear connection
6.1 General
6.1.1 Basis of design
6.1.2 Deformation capacity of shear connectors
6.1.3 Serviceability limit states
6.1.4 Ultimate limit states other than fatigue
6.1.5 Fatigue assessment based on nominal stress
ranges
6.1.6 Transient design situations during execution
6.2 Longitudinal shear force
6.2.1 General
6.2.2 Serviceability limit states, and fatigue
6.2.3 Ultimate limit states, other than fatigue,
for members in Class 1 or 2
6.2.4 Local effects of concentrated longitudinal
shear force
6.2.5 Temperature effects
6.2.6 Shrinkage modified by creep
6.3 Design resistance of shear connectors
6.3.1 General
6.3.2 Stud connectors in solid slabs
6.3.3 Headed studs used with profiled steel
sheeting
6.3.5 Hoops in solid slabs
6.3.6 Block connectors with hoops in solid slabs
6.3.8 Resistance to fatigue of stud connectors in
solid slabs
6.4 Detailing of the shear connection
6.4.1 General recommendations
6.4.2 Stud connectors
6.4.3 Headed studs used with profiled steel
sheeting
6.4.5 Hoop connectors
6.5 Friction grip bolts
6.6 Transverse reinforcement
6.6.1 Longitudinal shear in the slab
6.6.2 Design resistance to longitudinal shear
6.6.3 Contribution of profiled steel sheeting
6.6.4 Minimum transverse reinforcement in cast
in situ solid slabs
6.6.5 Longitudinal splitting
7 Composite slabs with profiled steel sheeting,
and composite plates
7.1 General
7.1.1 Scope
7.7 Composite plates
7.7.1 General
7.7.2 Design for local effects
7.7.3 Design for global effects
7.7.4 Design of shear connectors
8 Decks with precast concrete slabs
8.1 General
8.2 Actions
8.3 Partial safety factors for materials
8.4 Design, analysis and detailing of the bridge slab
8.5 Joints between steel beam and concrete slab
8.5.1 Bedding and tolerances
8.5.2 Corrosion
8.5.3 Shear connection and transverse reinforcement
9 Execution
9.2 Sequence of construction
9.4 Accuracy during construction, and quality control
9.4.1 Static deflection during and after concreting
9.4.3 Shear connection
9.4.4 Composite slabs with profiled steel sheeting
10 Design assisted by testing
10.1 General
10.3 Testing of composite floor slabs
Annex A Reference documents (not applicable)
Annex K Filler beam decks (Normative)
K.1 General
K.2 Requirements
K.3 Global analysis
K.4 Ultimate limit states
K.4.1 General
K.4.2 Bending moments
K.4.3 Vertical shear
K.4.4 Strength and stability of steel beams during
construction
K.5 Serviceability limit states
K.5.1 General
K.5.2 Cracking of concrete
K.5.3 Minimum reinforcement
K.5.4 Control of cracking
K.6 Detailing
K.7 Half-through bridges with transverse filler beams
K.7.1 General
K.7.2 Analysis
K.7.3 Shear in the direction of span of the
transverse beams
K.7.4 Detailing
Annex L Effects of tension stiffening in composite
bridges (Informative)
L.1 Scope
L.2 Tension members in bowstring arches and trusses
L.3 Tension members in composite beams
L.4 Stiffness
L.5 Calculation of the stress range in reinforcing,
prestressing and structural steel for fatigue
loading
L.5.1 General
L.5.2 Stress ranges in reinforcing and
prestressing steel
L.5.3 Stress ranges in structural steel
L.5.4 Range of longitudinal shear per unit
length, deltanu[f,E], for shear connectors
Covers a general basis for the design of composite bridges.
DocumentType |
Standard
|
Pages |
100
|
PublisherName |
National Standards Authority of Ireland
|
Status |
Superseded
|
SupersededBy |
Standards | Relationship |
ENV 1994-2 : DRAFT 97 | Identical |
ENV 1997-1 : 1994 | EUROCODE 7: GEOTECHNICAL DESIGN - GENERAL RULES |
ENV 1991-3:1995/AC:1998 | EUROCODE 1 - BASIS OF DESIGN AND ACTIONS ON STRUCTURES - TRAFFIC LOADS ON BRIDGES |
ENV 1993-2 : 1997 | EUROCODE 3: DESIGN OF STEEL STRUCTURES - PART 2: STEEL BRIDGES |
ENV 1992-1-4 : 1994 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - GENERAL RULES - LIGHTWEIGHT AGGREGATE CONCRETE WITH CLOSED STRUCTURE |
ENV 1991-2-1 : DRAFT 1995 | EUROCODE 1 - BASIS OF DESIGN AND ACTIONS ON STRUCTURES - DENSITIES, SELF-WEIGHT AND IMPOSED LOADS |
ENV 1992-2 : DRAFT 96 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - CONCRETE BRIDGES |
ENV 1991-2-6 : DRAFT 1997 | EUROCODE 1: BASIS OF DESIGN AND ACTIONS ON STRUCTURES - ACTIONS ON STRUCTURES - ACTIONS DURING EXECUTION |
ENV 1991-1 : DRAFT 1994 | EUROCODE 1: BASIS OF DESIGN AND ACTIONS ON STRUCTURES - BASIS OF DESIGN |
ENV 1992-1-3 : 1994 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - GENERAL RULES - PRECAST CONCRETE ELEMENTS AND STRUCTURES |
ENV 1090-1 : DRAFT 1996 | EXECUTION OF STEEL STRUCTURES - GENERAL RULES AND RULES FOR BUILDINGS |
ENV 1993-1-5 : DRAFT 97 | EUROCODE 3 - DESIGN OF STEEL STRUCTURES - GENERAL RULES - SUPPLEMENTARY RULES FOR PLANAR PLATED STRUCTURES WITHOUT TRANSVERSE LOADING |
ENV 1994-1-1 : 1992 | EUROCODE 4 - DESIGN OF COMPOSITE STEEL AND CONCRETE STRUCTURES - GENERAL RULES FOR BUILDINGS |
ENV 1992-1-6 : 1994 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - GENERAL RULES - PLAIN CONCRETE STRUCTURES |
ENV 1090-5 : DRAFT 1998 | EXECUTION OF STEEL STRUCTURES - SUPPLEMENTARY RULES FOR BRIDGES |
ENV 1991-2-4 : 1995 | EUROCODE 1: BASIS OF DESIGN AND ACTIONS ON STRUCTURES - ACTIONS ON STRUCTURES - WIND ACTIONS (TOGETHER WITH UNITED KINGDOM NATIONAL APPLICATION DOCUMENT) |
ENV 1998-2:1994/AC:1997 | EUROCODE 8 - DESIGN PROVISIONS FOR EARTHQUAKE RESISTANCE OF STRUCTURES - BRIDGES |
ENV 1992-3 : DRAFT 1998 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - PART 3: CONCRETE FOUNDATIONS |
ENV 1992-1-1 : DRAFT 91 COR 1992 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - GENERAL RULES AND RULES FOR BUILDINGS |
ENV 1991-2-7 : DRAFT 98 | EUROCODE 1 - BASIS OF DESIGN AND ACTIONS ON STRUCTURES - ACTIONS ON STRUCTURES - ACCIDENTAL ACTIONS DUE TO IMPACT AND EXPLOSIONS |
ENV 1991-2-5 : DRAFT AUG 1997 | EUROCODE 1: BASIS OF DESIGN AND ACTIONS ON STRUCTURES - ACTIONS ON STRUCTURES - THERMAL ACTIONS |
ENV 1992-1-5 : 1994 | EUROCODE 2: DESIGN OF CONCRETE STRUCTURES - GENERAL RULES - STRUCTURES WITH UNBONDED AND EXTERNAL PRESTRESSING TENDONS |
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