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"Alvarez drives home the point that for buildings and communities located in hurricane-prone regions, it is not a question of whether the area will be impacted, but when it will be impacted. The book makes a strong case for taking responsibility to understand the vulnerabilities of buildings and structures to hurricane impacts." Timothy Reinhold, P
The newest publication from the Tilt-Up Concrete Association is the second in a planned trilogy of resources covering the architecture, engineering and construction of Tilt-Up. Continuing the high quality with which ¿The Architecture of Tilt-Up¿ was printed and assembled, the new (10¿ x 10¿) book presents state-of-the art information and large colorful imagery of the construction process. Topics include: planning, slabs and foundations, panel layout and forming, reinforcement, inserts and embedded items, placing and finishing of the panels, lifting, setting and bracing of the panels, connections and finishing touches.
This report, FEMA-350 - Recommended Seismic Design Criteria for New Steel Moment-Frame Buildings has been developed by the SAC Joint Venture under contract to the Federal Emergency Management Agency (FEMA) to provide organizations engaged in the development of consensus design standards and building code provisions with recommended criteria for the design and construction of new buildings incorporating moment-resisting steel frame construction to resist the effects of earthquakes. It is one of a series of companion publications addressing the issue of the seismic performance of steel moment-frame buildings. The set of companion publications includes: FEMA-350 - Recommended Seismic Design Criteria for New Steel Moment-Frame Buildings. This publication provides recommended criteria, supplemental to FEMA-302 - 1997 NEHRP Recommended Provisions for Seismic Regulations for New Buildings and Other Structures, for the design and construction of steel moment-frame buildings and provides alternative performance-based design criteria. FEMA-351 - Recommended Seismic Evaluation and Upgrade Criteria for Existing Welded Steel Moment-Frame Buildings. This publication provides recommended methods to evaluate the probable performance of existing steel moment-frame buildings in future earthquakes and to retrofit these buildings for improved performance. FEMA-352 - Recommended Postearthquake Evaluation and Repair Criteria for Welded Steel Moment-Frame Buildings. This publication provides recommendations for performing postearthquake inspections to detect damage in steel moment-frame buildings following an earthquake, evaluating the damaged buildings to determine their safety in the postearthquake environment, and repairing damaged buildings. FEMA-353 - Recommended Specifications and Quality Assurance Guidelines for Steel Moment-Frame Construction for Seismic Applications. This publication provides recommended specifications for the fabrication and erection of steel moment frames for seismic applications. The recommended design criteria contained in the other companion documents are based on the material and workmanship standards contained in this document, which also includes discussion of the basis for the quality control and quality assurance criteria contained in the recommended specifications. The information contained in these recommended design criteria, hereinafter referred to as Recommended Criteria, is presented in the form of specific design and performance evaluation procedures together with supporting commentary explaining part of the basis for these recommendations.
The nation will remember 2004 as a record-setting year in terms of presidential disaster declarations and administered disaster aid. In 2004, President Bush issued 68 disaster declarations of which 27 were due to hurricanes. Time and again the U.S. was impacted by hurricane force winds and waves that damaged cities and small towns in 15 states, Puerto Rico, and the U.S. Virgin Islands. Of all the regions that endured the hurricane season, the State of Florida bore the brunt of the record-setting storms as Hurricanes Charley, Frances, Ivan, and Jeanne tested the federal and state fortitude in disaster response and recovery. Communities were devastated as wind and water damage from the four storms battered residential, commercial, industrial, and public facilities. Disaster assistance totaling more than $4.4 billion was approved for Floridians, and to date, 1.24 million storm victims have applied for federal and state assistance (FEMA 2005b). The financial impact of the season will likely exceed $20 billion, according to preliminary loss estimates from the Insurance Services Office's Property Claim Services (PCS). The four hurricanes that struck Florida in 2004 were all significant events; however, the hurricanes were each distinctive in terms of their wind and water action and resulting damages. The first of these, Charley (designated a Category 4), was the first design level wind event to strike the U.S. mainland since Hurricane Andrew (1992) and caused more wind damage than flood damage. Frances (Category 2) and Jeanne (Category 3), while not as strong as Charley, were still very damaging hurricanes resulting in additional wind damage. Hurricane Ivan delivered not only strong winds (Category 3), but also caused significant flood damage to buildings and other structures, even those built above the 100-year flood elevation. The impact of the four hurricanes was intensified by their back-to-back occurrence; three of the hurricanes followed similar paths or had overlapping damage swaths. Frances and Jeanne followed almost identical paths across Florida from the east coast (around Port St. Lucie) to the west coast (north of Tampa area). These two very wide storms crossed the path of Charley (which traveled west to east) in central Florida creating an overlap of impacted areas in Orange, Osceola, Polk, and Hardee counties. As a result of these overlapping impact swaths, damage resulting from the later hurricanes (Frances and Jeanne) was difficult to distinguish from earlier damage caused by Charley. For instance, roofs that failed during Frances or Jeanne may have been weakened or damaged by Charley and more prone to failure. For this reason, most of the recommendations and conclusions contained in this report are based on observations made after Hurricanes Charley and Ivan and are supported by observations made after Hurricanes Frances and Jeanne. Following Hurricanes Charley and Ivan, the FEMA Mitigation Assessment Teams (MATs) performed field observations to determine how well buildings in Florida and Alabama performed under stresses caused by the storms' wind and water impacts. A Rapid Response Data Collection Team performed field observations after Hurricane Frances that focused on critical and essential facilities; however an assessment was not performed after Jeanne, because Jeanne and Frances impacted a similar region. Overall, the MAT observed building performance success in structural systems designed and built after Hurricane Andrew. This Summary Report focuses on the ongoing need for improvement in building performance.
285 pages In the world of civil engineering and construction, the book Concrete: Building the Foundations of Modern Civilization stands as an indispensable and comprehensive guide to the versatile and enduring material that has shaped the modern world. This meticulously researched and expertly crafted volume delves into every aspect of concrete, from its historical origins to its cutting-edge applications in seismic design, sustainability, and cultural heritage preservation. Key Features: Historical Journey: Embark on a captivating historical journey through the evolution of concrete, tracing its roots from ancient mud bricks to the grandeur of Roman engineering. Explore how the Renaissance rekindled interest in concrete and how innovative minds in the 18th and 19th centuries laid the foundation for modern concrete technology. Science and Formulas: Delve into the mathematics and formulas that underpin concrete production, design, and structural engineering. Gain a deep understanding of the calculations involved in mixing concrete, determining loads, and optimizing structural elements. Seismic and Structural Engineering: Navigate the intricate world of concrete seismic engineering and structural design. Learn about the principles of strength, ductility, and load combinations that are fundamental to designing earthquake-resistant structures. Explore seismic analysis methods, dynamic analysis techniques, and mathematical calculations essential for safeguarding buildings in earthquake-prone regions. Material Properties: Uncover the physical and chemical properties of concrete, from its strength and durability to density, porosity, and thermal behavior. Discover how concrete's properties are interconnected and balanced to meet specific project requirements. Environmental Considerations: Examine concrete's role in sustainable construction practices, energy efficiency, and waste reduction. Explore case studies of innovative projects that exemplify responsible concrete use. Cultural Heritage: Explore the intersection of concrete with cultural heritage preservation. Dive into case studies of iconic landmarks and historic structures that showcase the delicate art of restoring and maintaining concrete heritage. Ethical and Social Considerations: Reflect on the ethical dimensions of concrete construction, including labor and safety practices, community engagement, sustainable sourcing, and cultural sensitivity. Explore case studies that illustrate best practices in these areas. Concrete: Building the Foundations of Modern Civilization is a meticulously researched and elegantly written work that caters to professionals, students, and enthusiasts alike. Whether you're a seasoned engineer seeking to deepen your knowledge or a newcomer to the world of concrete, this book offers a captivating and informative journey through the material that has shaped our cities and societies for millennia. From the foundations of knowledge to the heights of innovation, it's a concrete exploration like no other. # Chapter 1: Introduction to Concrete Section 1: The Origins of Concrete Concrete's historical roots and early developments. Section 2: Composition of Concrete Detailed analysis of concrete's ingredients and their roles. Section 3: Properties of Concrete A thorough examination of concrete's physical and chemical properties. Section 4: Applications of Concrete Concrete's versatility in construction projects around the world. # Chapter 2: Concrete Manufacturing Section 1: Mixing and Batching Exploring the process of mixing concrete ingredients. Section 2: Curing and Setting Understanding how concrete solidifies and strengthens. Section 3: Reinforcement Techniques An overview of reinforcement methods for added strength. Section 4: Sustainable Concrete Eco-friendly approaches to concrete production. # Chapter 3: Concrete Testing and Quality Control Section 1: Laboratory Testing In-depth analysis of concrete quality through lab tests. Section 2: Non-Destructive Testing Methods to assess concrete without damaging structures. Section 3: Quality Standards International standards for ensuring concrete durability. Section 4: Preventing Concrete Failures Strategies to avoid common concrete-related problems. # Chapter 4: Structural Design with Concrete Section 1: Structural Mechanics The principles of designing concrete structures. Section 2: Formwork and Molding Creating molds for various concrete shapes and sizes. Section 3: Prestressed Concrete Innovative techniques for enhancing concrete's load-bearing capacity. Section 4: Architectural Concrete Using concrete as an aesthetic element in architecture. # Chapter 5: Advances in Concrete Technology Section 1: Self-Healing Concrete Cutting-edge research on concrete that repairs itself. Section 2: High-Performance Concrete The development of ultra-strong and durable concrete types. Section 3: 3D Printing with Concrete Revolutionizing construction through 3D printing technology. Section 4: Smart Concrete Concrete embedded with sensors for real-time monitoring. # Chapter 6: Concrete in Infrastructure Section 1: Bridges and Highways Concrete's role in building sturdy transportation networks. Section 2: Dams and Reservoirs Applications of concrete in water management projects. Section 3: Skyscrapers and Tall Buildings Challenges and innovations in building with concrete at great heights. Section 4: Underground Construction The use of concrete in tunneling and underground facilities. # Chapter 7: Environmental Impact of Concrete Section 1: Carbon Footprint Assessing concrete's contribution to greenhouse gas emissions. ## Section 2: Sustainable Practices Efforts to reduce the environmental impact of concrete. Section 3: Recycling Concrete Methods for reusing and recycling concrete materials. Section 4: Future Sustainability Trends Anticipated advancements in eco-friendly concrete technology. # Chapter 8: Concrete in Extreme Conditions Section 1: Cold Weather Concreting Challenges and solutions in low-temperature environments. Section 2: Hot Weather Concreting Strategies for dealing with high-temperature conditions. Section 3: Seismic-Resistant Concrete Designing structures to withstand earthquakes. Section 4: Underwater Concrete Applications and techniques for working beneath water. # Chapter 9: Concrete in Art and Culture ## Section 1: Concrete in Sculpture Exploring the artistic use of concrete in sculptures. Section 2: Concrete in Architecture Architectural landmarks made of concrete around the world. Section 3: Cultural Significance Concrete's role in shaping cultural and historical narratives. Section 4: Public Art Installations Examples of concrete art installations in public spaces. # Chapter 10: Future Trends in Concrete Section 1: Nanotechnology in Concrete Emerging nanomaterials for enhancing concrete properties. Section 2: Artificial Intelligence in Construction How AI is revolutionizing concrete construction processes. Section 3: Bioconcrete Innovations in concrete that incorporate living organisms. Section 4: Space Exploration and Concrete Concrete's potential applications in extraterrestrial construction. # Chapter 11: Concrete in Transportation Section 1: Concrete Roads and Pavements The role of concrete in road construction and maintenance. Section 2: High-Speed Rail Infrastructure Concrete's importance in high-speed rail networks. Section 3: Airport Runways and Taxiways Applications of concrete in aviation infrastructure. Section 4: Ports and Harbors Concrete solutions for maritime transportation. # Chapter 12: Innovative Concrete Mixtures Section 1: Lightweight Concrete Exploring the properties and applications of lightweight concrete. Section 2: Fiber-Reinforced Concrete The benefits of adding fibers to enhance concrete strength. Section 3: High-Flow Concrete Improving workability and performance with high-flow concrete. Section 4: Colored and Decorative Concrete Using concrete as a design element with various colors and finishes. # Chapter 13: Sustainable Construction Practices Section 1: Green Building Certifications How concrete contributes to sustainable building certifications. Section 2: Energy-Efficient Concrete Innovations in concrete to improve energy efficiency. Section 3: Zero-Waste Construction Reducing waste in concrete construction projects. Section 4: Urban Heat Island Mitigation Concrete's role in mitigating heat islands in urban areas. # Chapter 14: Maintenance and Repair of Concrete Structures Section 1: Concrete Repair Methods Techniques for repairing damaged concrete structures. Section 2: Protective Coatings Using coatings to extend the life of concrete surfaces. Section 3: Corrosion Control Preventing and addressing corrosion in concrete. Section 4: Retrofitting for Strength Methods to strengthen existing concrete structures. # Chapter 15: Concrete in the Oil and Gas Industry Section 1: Offshore Platforms Concrete's use in constructing offshore drilling platforms. Section 2: Oil Well Cementing Applications of concrete in oil well construction. Section 3: Refineries and Petrochemical Plants Concrete's role in the infrastructure of these facilities. Section 4: Environmental Considerations Managing concrete-related environmental challenges in the industry. # Chapter 16: Concrete in Agriculture Section 1: Agricultural Infrastructure The use of concrete in farms and agricultural facilities. Section 2: Irrigation Systems Concrete's role in efficient water management in agriculture. Section 3: Storage Silos and Tanks Applications of concrete for storing agricultural products. Section 4: Sustainable Farming Practices How concrete supports environmentally friendly agriculture. # Chapter 17: Concrete in Healthcare Facilities Section 1: Hospital Construction The importance of concrete in building healthcare institutions. Section 2: Medical Research Facilities Concrete's role in constructing cutting-edge research centers. Section 3: Infection Control Using concrete to maintain sanitary healthcare environments. Section 4: Patient Comfort and Safety Design considerations for patient well-being in healthcare buildings. # Chapter 18: Concrete in Disaster Resilience Section 1: Disaster-Resistant Construction Designing structures to withstand natural disasters. Section 2: Emergency Shelter Construction Using concrete in the rapid construction of emergency shelters. Section 3: Post-Disaster Reconstruction Rebuilding communities with resilient concrete structures. Section 4: Lessons from Historic Disasters Analyzing past disasters to inform future concrete practices. # Chapter 19: Concrete and Cultural Heritage Section 1: Historic Preservation Preserving cultural landmarks made of concrete. Section 2: Restoration Techniques Methods for restoring aged concrete structures. Section 3: Museums and Cultural Centers Concrete's role in housing and displaying cultural artifacts. Section 4: Indigenous Concrete Traditions Exploring unique concrete practices of indigenous cultures. # Chapter 20: Ethical and Social Considerations Section 1: Labor and Safety Ensuring safe and ethical labor practices in concrete construction. Section 2: Community Engagement Involving communities in concrete projects and addressing their concerns. Section 3: Sustainable Sourcing Ethical considerations in the extraction of concrete materials. Section 4: Cultural Sensitivity Respecting cultural values when using concrete in diverse contexts. Addendum Concrete Seismic and Structural Engineering: Mathematical Aspects