BASICS OF RETAINING WALL DESIGN

Basics of Retaining Wall Design
Autor: Brooks,Hugh,P Nielsen,John

Design guide for earth retaining structures. Updated and expanded new 10th edtition covers nearly every type of earth retaining structure: cantilevered, counterfort, restrained (basement walls), gravity, segmental, sheet pile, sodier pile, and others. Current building code requirements are covered including IBC '12, MSJC '11, ACI 318-11, ASCE 7-10, CBC '13, and AASHTO.
Topics include types of retaining structures, basic soil mechanics, design of concrete and masonry walls, lateral earth pressures, seismic design, surcharges, pile and pier foundations, and swimming pool walls. Fourteen varied design examples. Comprehensive Appendix. Glossary of terminology

• Páginas: 260
• Tamaño: 21x30
• Edición: 10ª
• Idioma: Inglés
• Año: 2013
• PRECIO  52,00 EUROS

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DESIGN OF HIGHWAY BRIDGES AN LRFD APPROACH

Design of Highway Bridges: An LRFD Approach
Autor: Barker, Richard M., Puckett , Jay A. 


Up-to-date coverage of bridge design and analysis— revised to reflect the fifth edition of the AASHTO LRFD specifications
Design of Highway Bridges, Third Edition offers detailed coverage of engineering basics for the design of short- and medium-span bridges. Revised to conform with the latest fifth edition of the American Association of State Highway and Transportation Officials (AASHTO) LRFD Bridge Design Specifications, it is an excellent engineering resource for both professionals and students. This updated edition has been reorganized throughout, spreading the material into twenty shorter, more focused chapters that make information even easier to find and navigate. It also features:
•Expanded coverage of computer modeling, calibration of service limit states, rigid method system analysis, and concrete shear
•Information on key bridge types, selection principles, and aesthetic issues
•Dozens of worked problems that allow techniques to be applied to real-world problems and design specifications
•A new color insert of bridge photographs, including examples of historical and aesthetic significance
•New coverage of the "green" aspects of recycled steel
•Selected references for further studyFrom gaining a quick familiarity with the AASHTO LRFD specifications to seeking broader guidance on highway bridge design—Design of Highway Bridges is the one-stop, ready reference that puts information at your fingertips, while also serving as an excellent study guide and reference for the U.S. Professional Engineering Examination.
 
Table of Contents

Preface
Preface to the Second Edition
Preface to the First Edition

PART I GENERAL ASPECTS OF BRIDGE DESIGN

CHAPTER 1 INTRODUCTION TO BRIDGE ENGINEERING
 
1.1 A Bridge Is the Key Element in a Transportation System
1.2 Bridge Engineering in the United States
1.2.1 Stone Arch Bridges
1.2.2 Wooden Bridges
1.2.3 Metal Truss Bridges
1.2.4 Suspension Bridges
1.2.5 Metal Arch Bridges
1.2.6 Reinforced Concrete Bridges
1.2.7 Girder Bridges
1.2.8 Closing Remarks
1.3 Bridge Engineer—Planner, Architect, Designer, Constructor and Facility Manager
References
Problems

CHAPTER 2 SPECIFICATIONS AND BRIDGE FAILURES
 
2.1 Bridge Specifications
2.2 Implication of Bridge Failures on Practice
2.2.1 Silver Bridge, Point Pleasant, West Virginia, December 15, 1967
2.2.2 I-5 and I-210 Interchange, San Fernando, California, February 9, 1971
2.2.3 Sunshine Skyway, Tampa Bay, Florida, May 9, 1980
2.2.4 Mianus River Bridge, Greenwich, Connecticut, June 28, 1983
2.2.5 Schoharie Creek Bridge, Amsterdam, New York, April 5, 1987
2.2.6 Cypress Viaduct, Loma Prieta Earthquake, October 17, 1989
2.2.7 I-35W Bridge, Minneapolis,Minnesota, August 1, 2007
2.2.8 Failures During Construction
References
Problems

CHAPTER 3 BRIDGE AESTHETICS
 
3.1 Introduction
3.2 Nature of the Structural Design Process
3.2.1 Description and Justification
3.2.2 Public and Personal Knowledge
3.2.3 Regulation
3.2.4 Design Process
3.3 Aesthetics in Bridge Design
3.3.1 Definition of Aesthetics
3.3.2 Qualities of Aesthetic Design
3.3.3 Practical Guidelines for Medium- and Short-Span Bridges
3.3.4 Computer Modeling
3.3.5 Web References
3.3.6 Closing Remarks on Aesthetics
References
Problems

CHAPTER 4 BRIDGE TYPES AND SELECTION
 
4.1 Main Structure below the Deck Line
4.2 Main Structure above the Deck Line
4.3 Main Structure Coincides with the Deck Line
4.4 Closing Remarks on Bridge Types
4.5 Selection of Bridge Type
4.5.1 Factors to Be Considered
4.5.2 Bridge Types Used for Different Span Lengths
4.5.3 Closing Remarks
References
Problems

CHAPTER 5 DESIGN LIMIT STATES
 
5.1 Introduction
5.2 Development of Design Procedures
5.2.1 Allowable Stress Design
5.2.2 Variability of Loads
5.2.3 Shortcomings of Allowable Stress Design
5.2.4 Load and Resistance Factor Design
5.3 Design Limit States
5.3.1 General
5.3.2 Service Limit State
5.3.3 Fatigue and Fracture Limit State
5.3.4 Strength Limit State
5.3.5 Extreme Event Limit State
5.4 Closing Remarks
References
Problems

CHAPTER 6 PRINCIPLES OF PROBABILISTIC DESIGN

6.1 Introduction
6.1.1 Frequency Distribution and Mean Value
6.1.2 Standard Deviation
6.1.3 Probability Density Functions
6.1.4 Bias Factor
6.1.5 Coefficient of Variation
6.1.6 Probability of Failure
6.1.7 Safety Index ß
6.2 Calibration of LRFD Code
6.2.1 Overview of the Calibration Process
6.2.2 Calibration Using Reliability Theory
6.2.3 Calibration of Fitting with ASD
6.3 Closing Remarks
References
Problems 94

CHAPTER 7 GEOMETRIC DESIGN CONSIDERATIONS
 
7.1 Introduction to Geometric Roadway Considerations
7.2 Roadway Widths
7.3 Vertical Clearances
7.4 Interchanges
References
Problem

PART II LOADS AND ANALYSIS

CHAPTER 8 LOADS
 
8.1 Introduction
8.2 Gravity Loads
8.2.1 Permanent Loads
8.2.2 Transient Loads
8.3 Lateral Loads
8.3.1 Fluid Forces
8.3.2 Seismic Loads
8.3.3 Ice Forces
8.4 Forces Due to Deformations
8.4.1 Temperature
8.4.2 Creep and Shrinkage
8.4.3 Settlement
8.5 Collision Loads
8.5.1 Vessel Collision
8.5.2 Rail Collision
8.5.3 Vehicle Collision
8.6 Blast Loading
8.7 Summary
References
Problems

CHAPTER 9 INFLUENCE FUNCTIONS AND GIRDER-LINE ANALYSIS

9.1 Introduction
9.2 Definition
9.3 Statically Determinate Beams
9.3.1 Concentrated Loads
9.3.2 Uniform Loads
9.4 Muller–Breslau Principle
9.4.1 Betti’s Theorem
9.4.2 Theory of Muller–Breslau Principle
9.4.3 Qualitative Influence Functions
9.5 Statically Indeterminate Beams
9.5.1 Integration of Influence Functions
9.5.2 Relationship between Influence Functions
9.5.3 Muller–Breslau Principle for End Moments
9.5.4 Automation by Matrix Structural Analysis
9.6 Normalized Influence Functions
9.7 AASHTO Vehicle Loads
9.8 Influence Surfaces
9.9 Summary
References
Problems

CHAPTER 10 SYSTEM ANALYSIS—INTRODUCTION
 
10.1 Introduction
10.2 Safety of Methods
10.2.1 Equilibriumfor Safe Design
10.2.2 Stress Reversal and Residual Stress
10.2.3 Repetitive Overloads
10.2.4 Fatigue and Serviceability
10.3 Summary
References
Problem

CHAPTER 11 SYSTEM ANALYSIS—GRAVITY LOADS
 
11.1 Slab–Girder Bridges
11.2 Slab Bridges
11.3 Slabs in Slab–Girder Bridges
11.4 Box-Girder Bridges
11.5 Closing Remarks
References
Problems

CHAPTER 12 SYSTEM ANALYSIS—LATERAL, TEMPERATURE, SHRINKAGE AND PRESTRESS LOADS
 
12.1 Lateral Load Analysis
12.1.1 Wind Loads
12.1.2 Seismic Load Analysis
12.2 Temperature, Shrinkage, and Prestress
12.2.1 General
12.2.2 Prestressing
12.2.3 Temperature Effects
12.2.4 Shrinkage and Creep
12.3 Closing Remarks
References

PART III CONCRETE BRIDGES

CHAPTER 13 REINFORCED CONCRETE MATERIAL RESPONSE AND PROPERTIES

13.1 Introduction
13.2 Reinforced and Prestressed Concrete Material Response
13.3 Constituents of Fresh Concrete
13.4 Properties of Hardened Concrete
13.4.1 Short-Term Properties of Concrete
13.4.2 Long-Term Properties of Concrete
13.5 Properties of Steel Reinforcement
13.5.1 Nonprestressed Steel Reinforcement
13.5.2 Prestressing Steel
References
Problems
CHAPTER 14 BEHAVIOR OF REINFORCED CONCRETE MEMBERS
14.1 Limit States
14.1.1 Service Limit State
14.1.2 Fatigue Limit State
14.1.3 Strength Limit State
14.1.4 Extreme Event Limit State
14.2 Flexural Strength of Reinforced Concrete Members
14.2.1 Depth to Neutral Axis for Beams with Bonded Tendons
14.2.2 Depth to Neutral Axis for Beams with Unbonded Tendons
14.2.3 Nominal Flexural Strength
14.2.4 Ductility,Maximum Tensile Reinforcement,and Resistance Factor Adjustment
14.2.5 Minimum Tensile Reinforcement
14.2.6 Loss of Prestress
14.3 Shear Strength of Reinforced Concrete Members
14.3.1 Variable-Angle Truss Model
14.3.2 Modified Compression Field Theory
14.3.3 Shear Design Using Modified Compression Field Theory
14.4 Closing Remarks
References
Problems

CHAPTER 15 CONCRETE BARRIER STRENGTH AND DECK DESIGN
 
15.1 Concrete Barrier Strength
15.1.1 Strength of Uniform Thickness Barrier Wall
15.1.2 Strength of Variable Thickness Barrier Wall
15.1.3 Crash Testing of Barriers
15.2 Concrete Deck Design
References
Problems

CHAPTER 16 CONCRETE DESIGN EXAMPLES
 
16.1 Solid Slab Bridge Design
16.2 T-Beam Bridge Design
16.3 Prestressed Girder Bridge
References

PART IV STEEL BRIDGES

CHAPTER 17 STEEL BRIDGES

17.1 Introduction
17.2 Material Properties
17.2.1 Steelmaking Process: Traditional
17.2.2 Steelmaking Process: Mini Mills
17.2.3 Steelmaking Process: Environmental Considerations
17.2.4 Production of Finished Products
17.2.5 Residual Stresses
17.2.6 Heat Treatments
17.2.7 Classification of Structural Steels
17.2.8 Effects of Repeated Stress (Fatigue)
17.2.9 Brittle Fracture Considerations
17.3 Summary
References
Problem

CHAPTER 18 LIMIT STATES AND GENERAL REQUIREMENTS
 
18.1 Limit States
18.1.1 Service Limit State
18.1.2 Fatigue and Fracture Limit State
18.1.3 Strength Limit States
18.1.4 Extreme Event Limit State
18.2 General Design Requirements
18.2.1 Effective Length of Span
18.2.2 Dead-Load Camber
18.2.3 Minimum Thickness of Steel
18.2.4 Diaphragms and Cross Frames
18.2.5 Lateral Bracing
References
Problems

CHAPTER 19 STEEL COMPONENT RESISTANCE
 
19.1 Tensile Members
19.1.1 Types of Connections
19.1.2 Tensile Resistance—Specifications
19.1.3 Strength of Connections for Tension Members
19.2 Compression Members
19.2.1 Column Stability—Behavior
19.2.2 Inelastic Buckling—Behavior
19.2.3 Compressive Resistance—Specifications
19.2.4 Connections for Compression Members
19.3 I-Sections in Flexure
19.3.1 General
19.3.2 Yield Moment and Plastic Moment
19.3.3 Stability Related to Flexural Resistance
19.3.4 Limit States
19.3.5 Summary of I-Sections in Flexure
19.3.6 Closing Remarks on I-Sections in Flexure
19.4 Shear Resistance of I-Sections
19.4.1 Beam Action Shear Resistance
19.4.2 Tension Field Action Shear Resistance
19.4.3 Combined Shear Resistance
19.4.4 Shear Resistance of UnstiffenedWebs
19.5 Shear Connectors
19.5.1 Fatigue Limit State for Stud Connectors
19.5.2 Strength Limit State for Stud Connectors
19.6 Stiffeners
19.6.1 Transverse Intermediate Stiffeners
19.6.2 Bearing Stiffeners
References
Problems

CHAPTER 20 STEEL DESIGN EXAMPLES
 
20.1 Noncomposite Rolled Steel Beam Bridge
20.2 Composite Rolled Steel Beam Bridge
20.3 Multiple-Span Composite Steel Plate Girder Beam Bridge
References

APPENDIX A INFLUENCE FUNCTIONS FOR DECK ANALYSIS
APPENDIX B TRANSVERSE DECK MOMENTS PER AASHTO APPENDIX A4
APPENDIX C METAL REINFORCEMENT INFORMATION
APPENDIX D REFINED ESTIMATE OF TIME-DEPENDENT LOSSES
References
APPENDIX E NCHRP 12-33 PROJECT TEAM
Task Group
APPENDIX F LIVE-LOAD DISTRIBUTION—RIGIDMETHOD
 
INDEX

• Páginas: 544
• Tamaño: 17x24
• Edición: 3ª
• Idioma: Inglés
• Año: 2013
• PRECIO 152,00 Euros

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ESTRUCTURAS DE MADERA BASES DE CALCULO

Estructuras de Madera. Bases de Cálculo
Autor: Argüelles,Ramón , Arriaga, F


Desde la publicación del libro Estructuras de madera - Diseño y cálculo en el año 1996 y en segunda edición de 2000, que es precedente de la actual obra, se han producido importantes desarrollos en el ámbito europeo de la normativa de cálculo de estructuras de madera y en toda la normativa de apoyo de la determinación de las propiedades mecánicas de la madera y de la clasificación estructural. La última edición de aquella ya incluía alguno de los cambios que se estaban consolidando en los borradores de los Eurocódigos.
Además en España la normativa de cálculo de estructuras depende de la Administración. En el año 2006 se publicó el Código Técnico de la Edificación (CTE) que incluía entre varios aspectos de la edificación el relativo a la seguridad estructural. Todo este proceso de evolución ha venido acompañado de un desarrollo e implantación de la construcción con madera en España, como era de esperar. Este material tiene un futuro inevitablemente optimista, a pesar de las actuales circunstancias, por sus ventajas técnicas y  de repercusión medioambiental.
La presente publicación recoge principalmente, las bases de cálculo y permite la comprobación o proyecto de las piezas estructurales. Además, se han incluido capítulos que recogen los diversos productos de uso estructural que se han establecido de una manera decisiva en la construcción con madera, o los capítulos dedicados a las estructuras mixtas. Lógicamente, también se han unificado todas las unidades al Sistema Internacional, al que poco a poco los proyectistas de estructuras se van habituando.
Quedan otros temas por tratar, como las uniones, la organización constructiva, la patología y el cálculo en situación de incendio, que serán objeto de obras posteriores. Además, se plantea otro volumen dedicado al proyecto de estructuras y estará constituido por una serie de ejemplos de cálculo procurando representar los casos más frecuentes en la construcción con madera.
Este libro se dirige al estudiante y al profesional interesado en el proyecto y cálculo de estructuras de madera. El objetivo de la publicación es enseñar cómo se calcula, pero también exponer el soporte teórico que ayuda a entender de una manera más operativa el proceso del proyecto. Para ello el libro incluye numerosos ejemplos de aplicación  y una serie de anexos que permiten profundizar en algunos aspectos específicos

ÍNDICE

CAPITULO 1: INTRODUCCIÓN

1.1 GENERALIDADES .
1.2 ANATOMÍA DE LA MADERA
1.3 TENSIONES DE CRECIMIENTO
1.4 ANISOTROPÍA
1.5 ASPECTOS MEDIOAMBIENTALES DE LA MADERA

CAPITULO 2: PROPIEDADES FÍSICAS Y MECÁNICAS

2.1 PROPIEDADES FÍSICAS.
2.2 PROPIEDADES MECÁNICAS
2.2.1 Introducción
2.2.2 Propiedades mecánicas de la madera
2.2.3 Ensayos para la determinación de las propiedades mecánicas
2.2.4 Factores que influyen en las propiedades mecánicas
2.2.4.1 Contenido de humedad
2.2.4.2 Duración de la carga
2.2.4.3 Calidad de la madera.
2.2.4.4 Temperatura
2.2.5 Efecto del tamaño de la pieza en la resistencia.
2.3 VALORES CARACTERÌSTICOS DEL MATERIAL
2.3.1 Introducción
2.3.2 Valores característicos.

CAPÍTULO 3: PRODUCTOS DE MADERA CON USO EN ESTRUCTURAS

3.1 INTRODUCCIÓN
3.2 MADERA EN ROLLO
3.2.1 Introducción
3.2.2 Materiales
3.2.3 Dimensiones
3.2.4 Clasificación visual
3.2.5 Clases resistentes.
3.3 MADERA ASERRADA
3.4 MADERA EMPALMADA
3.5 MADERA ASERRADA ENCOLADA
3.6 MADERA LAMINADA ENCOLADA.
3.7 MADERA MICROLAMINADA.
3.8 MADERA RECONSTITUIDA
3.9 TABLEROS DERIVADOS DE LA MADERA
3.10 PANELES CONTRALAMINADOS DE MADERA

CAPITULO 4: BASES DE CÁLCULO

4.1 INTRODUCCION
4.1.1 Normativa
4.1.2 Vida útil.
4.1.3 Durabilidad
4.1.4 Estados límite
4.2 PROPIEDADES DEL MATERIAL
4.2.1 Factores que influyen en las propiedades.
4.2.1.1 Contenido de humedad de la madera. Clases de servicio
4.2.1.2 Duración de la carga. Clases de duración de la carga
4.2.1.3 Calidad de la madera. Clasificación
4.2.2 Aplicación de los valores característicos del 5º percentil y valores medios
4.2.3 Valores de cálculo.
4.3 ACCIONES
4.3.1 Clasificación de las acciones
4.3.2 Valores característicos de las acciones
4.3.3. Valores representativos de las acciones
4.3.4 Valores de cálculo de las acciones
4.4 SITUACIONES DE CÁLCULO
4.4.1 Estados límite últimos
4.4.2 Estados límite de servicio
4.5 ANÁLISIS ESTRUCTURAL
4.5.2 Análisis de piezas
4.5.3. Tipos estructurales

CAPITULO 5: DEFORMACIONES Y VIBRACIONES

5.1 CALCULO DE LA DEFORMACION
5.1.1 Deformación inicial o instantánea
5.1.2 Deformación diferida
5.1.2.1 Introducción
5.1.2.2 Factor de fluencia
5.1.3 Influencia de otros factores
5.1.3.1 Uniones
5.1.3.2 Condiciones ambientales
5.1.4 Cálculo de la deformación diferida en piezas con materiales con diferentes propiedades dependientes del tiempo
5.2 LIMITACION DE LA DEFORMACION
5.2.1 Introducción.
5.2.2 Limitaciones
5.3 VIBRACIONES
5.3.1 Introducción.
5.3.2 Limitación de las vibraciones
5.3.2.1 Vibraciones provocadas por maquinaria.
5.3.2.2 Forjados con uso residencial
5.3.2.4 Puentes peatonales

CAPITULO 6: COMPROBACION DE SECCIONES

6.1 GENERALIDADES Y NOTACION.
6.2 COMPROBACION DE TENSIONES NORMALES PARAL. A LA FIBRA
6.2.1 Tracción paralela a la fibra
6.2.2 Compresión paralela a la fibra
6.2.3 Flexión
6.2.3.1 Flexión simple
6.2.3.2 Flexión esviada
6.2.4 Solicitaciones combinadas
6.2.4.1 Flexotracción.
6.2.4.2 Flexocompresión
6.3 COMPROBACION DE LAS TENSIONES TANGENCIALES.
6.3.1 Cortante
6.3.1.1 Generalidades
6.3.1.2 Comprobación
6.3.1.3 Vigas con entalladuras en el apoyo
6.3.2 Torsión
6.3.2.1 Torsión pura
6.3.2.2 Torsión y cortante combinados.
6.4 COMPROBACION DE LAS TENSIONES PERPEND. A LA FIBRA
6.4.1 Tracción perpendicular a la fibra
6.4.2 Compresión inclinada respecto a la fibra
6.4.2.1 Compresión perpendicular
6.4.2.2 Compresión oblicua.
6.5 PIEZAS CON ENTALLADURAS
6.6 SISTEMAS DE CARGA COMPARTIDA

CAPITULO 7: INESTABILIDAD EN PIEZAS DE MADERA

7.1 COLUMNAS
7.1.1 Fundamentos
7.1.2 Determinación del coeficiente de inestabilidad kc
7.1.3 Longitudes de pandeo
7.1.4 Comprobación de secciones en flexocompresión
7.2 VIGAS
7.2.1 Fundamentos del vuelco lateral
7.2.2 Vigas de sección rectangular
7.2.3 Comprobación de secciones.
7.2.4 Disposiciones constructivas

CAPITULO 8: COMPROBACIONES SINGULARES EN PIEZAS DE MADERA LAMINADA DE SECCIÓN VARIABLE O DE DIRECTRIZ CURVA

8.1 INTRODUCCION.
8.2 CANTO VARIABLE Y DESVIO DE LA FIBRA
8.2.1 Estado de tensiones
8.2.2 Comprobación
8.3 PIEZAS CURVAS
8.3.1 Curvado de láminas
8.3.2 Tensiones normales
8.3.3 Tensiones perpendiculares a la fibra
8.4 ZONAS DE VERTICE
8.4.1 Introducción
8.4.2 Comprobación de tensiones normales
8.4.3 Comprobación de tensiones perpendiculares a la fibra

CAPÍTULO 9: VIGAS COMPUESTAS

9.1 INTRODUCCIÓN.
9.2 CONSIDERACIONES GENERALES PARA EL ANÁLISIS DE LAS TENSIONESY DEFORMACIONES EN VIGAS COMPUESTAS CON UNIONES ENCOLADAS
9.3 COMPROBACIÓN DE TENSIONES EN VIGAS CON ALMA ENCOLADA.
9.4 COMPROBACIÓN DE TENSIONES EN VIGAS CON ALAS DELGADAS ENCOLADAS.
9.5 VIGAS CON UNIONES MECÁNICAS
9.5.1 Introducción
9.5.2 Consideraciones generales
9.5.3 Método simplificado para el cálculo de vigas con uniones mecánicas

CAPÍTULO 10: COLUMNAS COMPUESTAS

10.1 INTRODUCCIÓN
10.2 CONSIDERACIONES GENERALES DEL CÁLCULO
10.3 COLUMNAS COMPUESTAS CON UNIONES MECÁNICAS
10.4 COLUMNAS COMPUESTAS CON TACOS SEPARADORES O CON PRESILLAS
10.4.1 Introducción e hipótesis
10.4.2 Capacidad de carga axial
10.4.3 Comprobación de los medios de unión, tacos y presillas
10.5 COLUMNAS DE CELOSÍA CON UNIONES ENCOLADAS O CLAVADAS
10.5.1 Introducción e hipótesis
10.5.2 Capacidad de carga
10.5.3 Esfuerzos cortantes
CAPITULO 11: PREDIMENSIONADO
11.1 INTRODUCCION
11.2 ESTRUCTURAS DE MADERA LAMINADA ENCOLADA
11.2.1 Consideraciones sobre el espesor de lámina
11.2.2 Predimensionado de la estructura principal
11.2.3 Estructura secundaria. Correas
11.2.4 Estimación del peso propio
11.2.5 Aspectos más característicos de la comprobación de algunos sistemas estructurales.
11.3 ESTRUCTURAS DE MADERA ASERRADA.
11.3.1 Forjados
11.3.2 Cerchas ligeras.
11.3.3 Cerchas de madera maciza con grandes escuadrías
11.3.4 Cerchas con escuadrías medianas

ANEXOS

A. Elasticidad en los materiales ortótropos
B. Metodología de ensayo para la determinación de las propiedades mecánicas
C. Determinación de las propiedades mecánicas a partir de probetas pequeñas y libres de defectos
D. Efecto de la duración de la carga en la resistencia
E. Efecto de la edad de la estructura en la capacidad resistente
F. Clasificación de la madera
G. Valores característicos de las propiedades de los tableros.
H. Efecto de la variación del contenido de humedad en las deformaciones y tensiones de las piezas de madera
I. Fundamentos del factor de pandeo en columnas, kc
J. Fundamentos teóricos sobre el pandeo globalde la estructura y longitudes eficaces de sus barras

• Páginas: 531
• Tamaño: 17x24
• Edición: 3ª
• Idioma: Español
• Año: 2013
• PRECIO  52,00 EUROS

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SEISMIC DESIGN OF STEEL STRUCTURES

 

Seismic Design of Steel Structures
Autor: Gioncu,Victor , Mazzolani,Federico


Providing real world applications for different structural types and seismic characteristics, Seismic Design of Steel Structures combines knowledge of seismic behavior of steel structures with the principles of earthquake engineering. This book focuses on seismic design, and concentrates specifically on seismic-resistant steel structures.
Drawing on experience from the Northridge to the Tohoku earthquakes, it combines understanding of the seismic behavior of steel structures with the principles of earthquake engineering. The book focuses on the global as well as local behavior of steel structures and their effective seismic-resistant design. It recognises different types of earthquakes, takes into account the especial danger of fire after earthquake, and proposes new bracing and connecting systems for new seismic resistant steel structures, and also for upgrading existing reinforced concrete structures.
    Includes the results of the extensive use of the DUCTROCT M computer program, which is used for the evaluation of the seismic available ductility, both monotonic and cyclic, for different types of earthquakes
    Demonstrates good design principles by highlighting the behavior of seismic-resistant steel structures in many applications from around the world
    Provides a methodological approach, making a clear distinction between strong and low-to-moderate seismic regions
This book serves as a reference for structural engineers involved in seismic design, as well as researchers and graduate students of seismic structural analysis and design

CONTENTS

Failure of a myth

The myth of steel as a perfect material for seismic-resistant structures
Behavior of steel structures during American and Asian earthquakes
Behavior of steel structures during the European earthquakes
Engineering lessons learned from the last strong earthquakes
References

Steel against earthquakes

Steel as the material of choice for seismic areas
Development of steel structural systems
References
Challenges in seismic design
Gap in seismic design methodologies
Earthquake types
Strong seismic regions
Low-to-moderate seismic regions
Proposals for improving the new code provisions
References

New generation of steel structures

Introduction
Improving existing solutions
New solutions of bracing systems
New solutions for connections
References
Advances in steel beam ductility
New concepts on structural ductility
DUCTROT-M Computer program
Monotonic available ductility
Local ductility under far-field earthquakes
Near-field earthquake effects on the available ductility of steel beams
Acknowledgments
References

Fire after earthquake

Introduction
Structural behavior under the effect of fire
From the historical events to date
Post-earthquake fire and risk management
Computational aspects
Analysis assumptions
Structural behavior
Methodology for assessing robustness
Conclusive remarks
References

Index

• Páginas: 525
• Tamaño: 17x24
• Edición: 1ª
• Idioma: Inglés
• Año: 2013
• PRECIO  130,00 Euros

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THE FOUNDATION ENGINEERING HANDBOOK

 

The Foundation Engineering Handbook

 Autor: Gunaratne,Manjriker


Considering how structures interact with soil, and building proper foundations, is vital to ensuring public safety and to the longevity of buildings. Understanding the strength and compressibility of subsurface soil is essential to the foundation engineer. The Foundation Engineering Handbook, Second Edition provides the fundamentals of foundation engineering needed by professional engineers and engineering students.
It presents both classical and state-of-the-art design and analysis techniques for earthen structures and examines the principles and design methods of foundation engineering needed for design of building foundations, embankments, and earth retaining structures. It covers basic soil mechanics, and soil and groundwater modeling concepts, along with the latest research results.
What’s New in the Second Edition:
    Adds alternative analytical techniques to nearly every chapter
    Supplements existing material with new content
    Includes additional applications in the state of the art such as unsaturated soil mechanics, analysis of transient flow through soils, deep foundation construction monitoring based on thermal integrity profiling, and updated ground remediation techniques
    Covers reliability-based design and LRFD (load resistance factor design) concepts not addressed in most foundation engineering texts
    Provides more than 500 illustrations and over 1,300 equations
The text serves as an ideal resource for practicing foundation and geotechnical engineers, as well as a supplemental textbook for both undergraduate and graduate levels.
"This book provides an up-to-date coverage of foundation engineering with useful material that is suitable for seniors and graduate students. It can also be used as a reference by the practicing engineer. The book is concisely and clearly written with many helpful examples. …Topics are appropriate as a foundation engineering textbook."
––Hsein Juang, Clemson University, South Carolina, USA
"This handbook is comprehensive and detailed. It presents the content in simple English and has enough background of modern engineering principles to use in a teaching setting. It is nice to see enough background in critical state soil mechanics combined with conventional foundation engineering techniques."
––Professor Ronaldo Luna, Missouri University of Science & Technology, Rolla, USA

Contents

Review of Soil Mechanics Concepts and Analytical Techniques Used in Foundation Engineering
Manjriker Gunaratne

In Situ Soil Testing
Austin Gray Mullins

Spread Footings: Analysis and Design
Manjriker Gunaratne

Geotechnical Design of Combined Spread Footings
Manjriker Gunaratne

Structural Design of Foundations
Panchy Arumugasaamy

Design of Driven Piles and Pile Groups
Manjriker Gunaratne

Design of Drilled Shafts
Austin Gray Mullins

Design of Laterally Loaded Piles
Manjriker Gunaratne

Construction Monitoring and Testing Methods of Driven Piles
Manjriker Gunaratne and Austin Gray Mullins

Retaining Walls: Analysis and Design
Alaa Ashmawy

Stability Analysis and Design of Slopes
Manjriker Gunaratne

Methods of Soft Ground Improvement
James D. Hussin

Impact of Groundwater on the Design of Earthen Structures
Manjriker Gunaratne

Index

• Páginas: 727
• Tamaño: 17x24
• Edición: 2ª
• Idioma: Inglés
• Año: 2013
• PRECIO   145,00 Euros

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Shock Transmission Units in Construction

 

Shock Transmission Units in Construction 
Autor: Patel, Dinesh J

Recent earthquakes around the world have confirmed the potential for a large seismic event to cause unprecedented levels of destruction. Shock transmission units (STUs) have been used in several projects as one of the most effective instruments in preventing widespread damage from seismic activities and structural movement. Shock Transmission Units in Construction is the first book to explore the procurement, selection, testing, installation and maintenance processes of STUs, as well as technological developments in the field of seismic protection.
This book covers the use of STUs as both a preventative measure, fitted to a structure before a seismic occurrence, and as a seismic protection system, retrofitted to prevent further damage. Drawing on his experiences of supervising the construction of the first bridges in India and the Philippines to use STUs, Dinesh Patel explores the application of STUs on a number of different projects, including new and existing highway and rail bridges, suspension and cable stayed bridges, buildings, structures, nuclear power plants and pipelines.
Shock Transmission Units in Construction contains case studies, photographs and illustrative diagrams to provide a clear guide to the application of STUs in numerous construction projects, as well as:
    A thorough introduction to this widely-practiced, but still little understood engineering practice, challenging critics by demonstrating the benefits and reliability of STUs in various contexts.
    A study of current STU brands and manufacturers, and the ways in which different types of STUs have been used in existing projects.
    Examples of STU application in India, Taiwan, Indonesia, Malaysia, South Korea, Hong Kong, Denmark, Rome, Italy, UK, Saudi Arabia, Turkey, Laos, Indonesia, Canada, USA and the UK.
    An analysis of the cost efficiency of retro-fitting practices.
Shock Transmission Units in Construction aims to provide best practice guidance in helping both new and experienced engineers to select the most appropriate STU for construction projects, thus ensuring that they are used to their full potential. It is hoped that this will lead to more varied usage and the development of innovative STU derivatives for application in future projects
About the author:
Dinesh J. Patel graduated from the University of London, UK with a degree in Civil Engineering and obtained his Masters in Structural Engineering from the University of New South Wales, Sydney, Australia. He then supervised the design and construction of bridge structures across the world, including projects in the UK, Canada, Australia, Nigeria, Saudi-Arabia, Indonesia, India, British Guyana and the Philippines, as well as working with various international consulting engineering firms on bridge projects funded by the World Bank, the Asian Development Bank and the Japanese Government.
Mr Patel supervised the construction of the Badiwan Bridge, Baguio - the first bridge in the Philippines to use Shock Transmission Units – an experience which enabled him to procure, select, test and install the STUs on the Second Bassein Creek Bridge, Mumbai, India. He was employed by N. D. Lea International, Canada, as resident Engineer/Team Leader to supervise the construction of this project, the first bridge in India to use Shock Transmission Units. The bridge was also awarded the first prize for innovation in construction engineering in 2001 by the Indian Institution of Bridge Engineering.
Mr Patel has written and presented many papers on bridge engineering and shock transmission units. His paper entitled “Shock transmission units (STUs) for earthquake load distribution on the World Bank funded Second Bassein Creek Bridge in Maharashtra”, published in the Journal of the Indian Roads Congress, was awarded a certificate of merit by the Indian Road Congress in 2002.
Mr Patel’s involvement in the Second Bassein Creek Bridge made him realise the potential for retrofitting STUs to bridges in countries with revised and upgraded earthquake zones to strengthen bridges for earthquake loading. In the absence of technical literature or specification in the Indian bridge design code on the subject of STUs, Mr Patel hopes to use this book to share his experience and best practice guidance to help future bridge engineers to procure, test and install STUs to a high standard ensure that they select the most appropriate STUs for their projects.

CONTENTS

- Preface
- Acknowledgements
- About the author
EVOLUTION OF SHOCK TRANSMISSION UNITS ( STUs)

- Introduction
- History of the evolution of STUs
- Progression of early STUs to present-day,maintenance-free compact STUs
- References
- Further reading

SEISMIC PROTECTION SYSTEMS

- Introductin
- Energy concepts for seismic protection of structures
- Energy approach
- Seismic hardware
- References
- Further reading
SHOCK TRANSMISSION UNITS AND THEIR APPLICATIONS

- Introduction
- Modern STUs
- Principle of operation of STUs
- Function of STUs
- Different brands of STUs and their dimensions
- Applications of STUs
- Service life of STUs
- Further reading

STUs FOR NEW HIGHWAY BRIDGES

- Introduction
- Second Bassein,Creek Bridge,Mumbai, India
- New Paksey Bridge,Bangladesh, India
- New Golf Bridge,Riggins, Idaho. Usa
- References
- Further reading

STUs  FOR NEW AND EXISTING RAILWAY BRIDGES

- Introduction
- Railway bridges over rivers in Indonesia – new bridges 6.3.
- Taiwan high-speed rail project – a new bridge 6.4.
- Light rail transit project, Kuala Lumpur, Malaysia – new bridge
- Baswich Viaduct, UK – a new deck with an existing substructure
- Docklands Light Railway (DLR), London, UK – an existing bridge
- Putney Bridge, London, UK – an existing bridge
- Neath Railway Bridge, South Wales, UK – an existing bridge References Further reading

STUs FOR CABLE-STAYED AND SUSPENSION BRIDGES

- Introduction
- Storebaelt suspension bridge, Denmark – a new bridge 7
- Sidney Lanier Bridge, Georgia, USA – a new bridge
- Second Severn Bridge, UK – a new cable-stayed bridge
- Maysville Bridge, Ohio, USA – a new bridge
- Seohae Grand Bridge, South Korea – a new bridge
- Stonecutters Bridge, Hong Kong – a new cable-stayed bridge References Further reading

STUs FOR BUILDINGS

- Introduction
- Roof structure of Rome Stadium, Italy
- Retrofit of Ataturk International Airport terminal building, Istanbul, Turkey
- The upper basilica of San Francesco, Assisi, Italy
- Official reception building, Riyadh, Kingdom of Saudi Arabia References

THE SNUBBER- A SPECIAL TYPE OF STU FOR NUCLEAR POWER PLANT AND  PIPELINES

- Introduction
- General description
- Types of snubber
- Design specification and load testing
- Installation
- Inspection and maintenance References

MISCELLANEOUS APPLICATIONS OF STUs

- Introduction
- Rotational STUs for floating pontoons
- STUs for bridge parapets
- STUs for vertical movement and impact transmission
- STUs as unidirectional struts or ties
- STUs in a transverse direction on a bridge
- STUs for strengthening against collision forces -
- STUs used temporarily during construction
- STUs for the replacement of a reinforced-concrete cross-head
- STUs integrated in pot bearings
- STUs for access stairs and escalator supporting structures References Further reading

INSTALLATION OF STUs ON STRUCTURES

- Introduction
- Design of connections
- Standard STU connections for highway and railway bridges
- Second Bassein Creek Bridge, India
- Installation of STUs on the Mekong River Bridge, Laos -
- CR111 Bridge, Suffolk County, USA
- Carquinez Bridge, California, USA
- Installation of STUs on cable-stayed and suspension bridges
- References
- Further reading

COST-EFFECTIVENESS OF STUs

- Introduction
- Second Bassein Creek Bridge, Mumbai, India
- Paksey Bridge, Bangladesh
- Carquinez Bridge, California, USA
- Cable-stayed and suspension bridges
- Railway bridges over rivers in Indonesia
- Conclusions References Further reading

LOAD TESTING OF STUs

- Introduction
- 2002 AASHTO interim specification for STUs
- Second Bassein Creek Bridge, Mumbai, India
- Paksey Bridge, Bangladesh
- Carquinez Bridge, California, USA References
 
INSPECTION AND MAINTENANCE OF STUs

- Introduction
- Inspection
- Maintenance
- Removal and replacement
- Maintenance period
- Load testing of installed STUs
- Load testing of installed STUs for the Stour Viaduct, Kent, UK Further reading

DESIGN GUIDELINES FOR PROCUREMENT AND SELECTION O STUs

- Introduction
- Design guideline
- Procurement and selection
- Final approval References

DERIVATIVES OF STUs

- Introduction
- Hydraulic dampers
- Crawl connector STUs
- Force limiter STUs
- Load and displacement equaliser STUs
- Shock absorber STUs Reference

STUs IN CONJUNCTION WITH OTHER SEISMIC-PROTECTION DEVICES

- Introduction
- Mortaiolo Viaduct, Italy
- Jamuna multipurpose bridge, Bangladesh
- Marquam Bridge, Oregon, USA References

MANUFACTURES OF STUs

LABORATORIES FOR TESTING STUs

• ISBN: 9780727757135
• Páginas: 226
• Tamaño: 19x24
• Edición: 1ª
• Idioma: Inglés
• Año: 2013
• PRECIO  122,00 Euros  

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SMALL DAMS PLANNING

Small Dams. 

Planning, Construction and Maintenance

 

Small Dams. Planning, Construction and Maintenance  

Autor: Lewis,Barry

 

Farmers are well aware of the need to boost productivity. In the face of the greater competition for domestic and overseas markets, the farmer who wants to succeed has to tak a business approach to increasing efficiency, reducing costs and improving output. In this environment, water becomes an economic factor and its provision a matter for careful deliberation.
This book is designed as a guide for dam owners, engineering students, government agencies, developers, and earthmoving contractors who are responsible for designing, building and using the majority of farm water storages. It is also designed for engineers who have not specialised in small earth dam design for agricultural hydrology who need to design small water storage schemes.
'Small Dams' provides a practial approach and guide to determining catchment yield and the amount of water required in a dam. It also advises on working with engineers and contractors, and outlines the causes of dam failures and how to remedy problems quickly. It further covers relevant legislation, environmental and ecological issues from a global perspective, with explicit reference to various countries around the world.
By employing the principles in this volume, in conjuction with the advise of suitably experienced engineers and contractors, small dam builders, such as farmers and land owners, will reduce the risk of failure and ensure long-term success of their dams. An invaluable reference resource for anyone who owns or plans to own a dam, and a useful reference for agencies, contractors and engineers.

CONTENTS

1. Planning
Assessing water needs
Assessment of catchment yield
Dam site selection
Types of farm storages
Dam storage size
Using a dam in drought
Fire Fighting
2. Investigation
Soil testing
Site selection criteria
Foundation materials
Embankment materials
Site investigation of materials
Analysis of soil
Location of soil
Unsuitable material
3. Design
Items that need to be considered
Flood flow estimation
Outlet structures
Pipelines through embankments
Earth and water computations
Estimate of costs
4. Documentation
Collation of plans and specification
Collecting basic design data
Assembly of data
Construction documents and drawings
Final review and approval
5. Construction
Approval for dam building
Selecting your dam builders
How to build a dam
Steps in constructing a dam
Compaction
Soil moisture
Allowance for settlement
Equipment
Installation of outlet pipe
Checking for compliance with standards
Final inspection and measurements
6. Maintenance
Safety surveillance
Inspection procedures
Causes of dam failures
Dam Leakage
7. Water
Water quantity
Water quality
Water treatment for human consumption
Algae in farm water supplies
Salt in dam water
8. Ecology
Wildlife and plants in dams
Water plants in dams
Using herbicides near water
Vegetation on and around dams
Yabbies
9. Commercial
Fish farming
Yabby farming
Native fauna and total ecosystem management
Licensing process
10. Legal
Legal and policy aspects in Australia
Liability
Responsibility of dam owners
Dam failure
Designer and earthmoving contractor(s)
Property insurance
Appendix 1 A glossary of terminology
Appendix 2 Engineering specifications for an earth-fill farm dam
Appendix 3 Metric and imperial conversion tables
References and suggested further reading

• Páginas: 210
• Tamaño: 17x24
• Edición: 1ª
• Idioma: Inglés
• Año: 2013
• PRECIO   86,00 Euros

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