EARTHQUAKE RESISTANT BUILDINGS
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An earthquake (also known as a quake, tremor or temblor) is the shaking of the surface of the Earth, resulting from the sudden release of energy in the Earth's lithosphere that creates seismic waves. Earthquakes can range in size from those that are so weak that they cannot be felt to those violent enough to toss people around and destroy whole cities. The seismicity or seismic activity of an area refers to the frequency, type and size of earthquakes experienced over a period of time. The word tremor is also used for non-earthquake seismic rumbling. At the Earth's surface, earthquakes manifest themselves by shaking and sometimes displacement of the ground. When the epicenter of a large earthquake is located offshore, the seabed may be displaced sufficiently to cause a tsunami. Earthquakes can also trigger landslides, and occasionally volcanic activity. In its most general sense, the word earthquake is used to describe any seismic event — whether natural or caused by humans — that generates seismic waves. Earthquakes are caused mostly by rupture of geological faults, but also by other events such as volcanic activity, landslides, mine blasts, and nuclear tests. An earthquake's point of initial rupture is called its focus or hypocenter. The epicenter is the point at ground level directly above the hypocenter.
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Earthquake Resistant Masonry Buildings
This document discusses earthquake resistant design of masonry buildings. It provides general principles for earthquake resistant structures, including using materials that are not brittle and will resist sudden collapse. It describes various construction systems for masonry, such as unreinforced, reinforced, and confined masonry. Key elements like walls, lintels, floors, and roofs are discussed. Design considerations include using uniformly distributed walls, adequate foundations, reinforced partitions, and limiting spans of cantilever slabs. Overall, masonry buildings can perform well in earthquakes if built with good quality materials and construction according to these design principles.
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This document summarizes techniques for earthquake resistant building construction. It discusses how earthquake resistant buildings differ from traditional buildings in their design. Some techniques discussed include using reinforced hollow concrete block masonry, which uses reinforced blocks as load-bearing walls and shear walls. Mid-level isolation is described as installing base isolation systems on intermediate floors of existing buildings. Slurry infiltrated mat concrete is presented as a new type of concrete being developed to prevent building collapse. Traditional earthquake resistant housing styles from various regions of India are also overviewed.
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Earthquake resisting building structures are designed to minimize damage and loss of life from earthquakes. Passive systems like shear walls, bracing, and dampers are conventional techniques used to resist earthquake forces and absorb seismic energy. Active control systems integrate real-time processors to improve safety. Other earthquake resistant methods include using lightweight materials, rollers, base isolation, and avoiding weak structural elements. Properly designing buildings with features like thick slabs, cross walls, and symmetrical reinforcement can increase a building's ability to withstand earthquake forces.
Earthquake resistant structure
hie guys
Its a small presentation on Earthquake Resistant Structures
some basic fundamentals about its causes its effect and few techniques to resist it..
earthquake resistant design
1. Structures in Kobe built since 1981 that were designed to strict seismic codes mostly withstood the 1995 Kobe earthquake, while newly built ductile-frame high-rise buildings were generally undamaged.
2. Modern earthquake engineering aims to create earthquake-resistant designs and construction techniques to build all types of structures, using state-of-the-art technology, materials science, and testing.
3. Key strategies for earthquake-resistant design include base isolation, increasing damping, and using devices like viscous and friction dampers to absorb seismic energy.
Earthquake and earthquake resistant design
This document discusses various earthquake-resistant features used in building design including:
1) Using beams as ductile weak links rather than columns through strong-column weak-beam design.
2) Improving masonry wall behavior by controlling wall dimensions and heights, ensuring proper construction and bonding, and adding horizontal reinforcement.
3) Using shear walls in reinforced concrete buildings to provide strength and stiffness throughout the building height.
Earthquake resistant building construction
1 INTRODUCTION
2 EARTHQUAKE THEORY
3 EARTHQUAKE MAGNITUDE AND ENERGY
4 EFFECTS OF EARTHQUAKES
5 MAJOR EARTHQUAKES
6 NOTABLE EARTHQUAKES AND THEIR ESTIMATED
MAGNITUDE
7 HOW EARTHQUAKE RESISTANT CONSTRUCTION IS
DIFFERENT
8 SEISMIC DESIGN PHILOSOPHY
9 EFFECT OF EARTHQUAKE ON REINFORCED CONCRETE BUILDINGS
10 ROLES OF FLOOR AND MASONRY WALLS SLABS
11 STRENGTH HIERARCHY
12 EARTHQUAKE RESISTANT BUILDING
13 EARTHQUAKE DESIGN PHILOSOPHY
14 REMEDIAL MEASURES TO MINIMISE THE LOSSES DUE TO EARTHQUAKES
15 EARTHQUAKE RESISTANT BUILDING CONSTRUCTION WITH REINFORCED HOLLOW CONCRETE BLOCK(RHCBM)
16 STRUCTURAL FEATURES
17 STRUCTURAL ADVANTAGES
18 CONSTRUCTIONAL ADVANTAGES
19 ARCHITECTURAL AND OTHER ADVANTAGES
20 STUDIES ON THE COMPARATIVE COST ECONOMICS OF RHCBM
21 MID-LEVEL ISOLATION 32-34
22 EARTHQUAKE RESISTANCE BUILDING USING SEISMIC ISOLATION SYSTEMS WITH SLIDING ON CONCAVE SURFACE
23 DESCRIPTION
24 CONCEPT OF FRICTION PENDULUM BEARING
25 SLIDING PENDULUM SEISMIC ISOLATION SYSTEM
26 BACKGROUND OF THE INVENTION
27 BRIEF SUMMARY OF THE INVENTION
28 DETAILED DESCRIPTION OF THE INVENTION
29 ESTIMATION
30 CONCLUSION
31 BIBLIOGRAPHY
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A report format presentation of earthquake-resistance construction techniques, stressing upon the relevance of such techniques in the architecture industry.
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This document summarizes techniques for earthquake resistant building construction. It discusses how earthquake resistant buildings differ from traditional buildings in their design. Some techniques discussed include using reinforced hollow concrete block masonry, which uses reinforced blocks as load-bearing walls and shear walls. Mid-level isolation is described as installing base isolation systems on intermediate floors of existing buildings. Slurry infiltrated mat concrete is presented as a new type of concrete being developed to prevent building collapse. Traditional earthquake resistant housing styles from various regions of India are also overviewed.
Earthquake Resisting Building Structur
Earthquake resisting building structures are designed to minimize damage and loss of life from earthquakes. Passive systems like shear walls, bracing, and dampers are conventional techniques used to resist earthquake forces and absorb seismic energy. Active control systems integrate real-time processors to improve safety. Other earthquake resistant methods include using lightweight materials, rollers, base isolation, and avoiding weak structural elements. Properly designing buildings with features like thick slabs, cross walls, and symmetrical reinforcement can increase a building's ability to withstand earthquake forces.
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earthquake resistant design
1. Structures in Kobe built since 1981 that were designed to strict seismic codes mostly withstood the 1995 Kobe earthquake, while newly built ductile-frame high-rise buildings were generally undamaged.
2. Modern earthquake engineering aims to create earthquake-resistant designs and construction techniques to build all types of structures, using state-of-the-art technology, materials science, and testing.
3. Key strategies for earthquake-resistant design include base isolation, increasing damping, and using devices like viscous and friction dampers to absorb seismic energy.
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This document discusses various earthquake-resistant features used in building design including:
1) Using beams as ductile weak links rather than columns through strong-column weak-beam design.
2) Improving masonry wall behavior by controlling wall dimensions and heights, ensuring proper construction and bonding, and adding horizontal reinforcement.
3) Using shear walls in reinforced concrete buildings to provide strength and stiffness throughout the building height.
Earthquake resistant building construction
1 INTRODUCTION
2 EARTHQUAKE THEORY
3 EARTHQUAKE MAGNITUDE AND ENERGY
4 EFFECTS OF EARTHQUAKES
5 MAJOR EARTHQUAKES
6 NOTABLE EARTHQUAKES AND THEIR ESTIMATED
MAGNITUDE
7 HOW EARTHQUAKE RESISTANT CONSTRUCTION IS
DIFFERENT
8 SEISMIC DESIGN PHILOSOPHY
9 EFFECT OF EARTHQUAKE ON REINFORCED CONCRETE BUILDINGS
10 ROLES OF FLOOR AND MASONRY WALLS SLABS
11 STRENGTH HIERARCHY
12 EARTHQUAKE RESISTANT BUILDING
13 EARTHQUAKE DESIGN PHILOSOPHY
14 REMEDIAL MEASURES TO MINIMISE THE LOSSES DUE TO EARTHQUAKES
15 EARTHQUAKE RESISTANT BUILDING CONSTRUCTION WITH REINFORCED HOLLOW CONCRETE BLOCK(RHCBM)
16 STRUCTURAL FEATURES
17 STRUCTURAL ADVANTAGES
18 CONSTRUCTIONAL ADVANTAGES
19 ARCHITECTURAL AND OTHER ADVANTAGES
20 STUDIES ON THE COMPARATIVE COST ECONOMICS OF RHCBM
21 MID-LEVEL ISOLATION 32-34
22 EARTHQUAKE RESISTANCE BUILDING USING SEISMIC ISOLATION SYSTEMS WITH SLIDING ON CONCAVE SURFACE
23 DESCRIPTION
24 CONCEPT OF FRICTION PENDULUM BEARING
25 SLIDING PENDULUM SEISMIC ISOLATION SYSTEM
26 BACKGROUND OF THE INVENTION
27 BRIEF SUMMARY OF THE INVENTION
28 DETAILED DESCRIPTION OF THE INVENTION
29 ESTIMATION
30 CONCLUSION
31 BIBLIOGRAPHY
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Base isolation
Base isolation is a seismic protection system that separates a structure from its foundation, allowing the structure to remain largely motionless during an earthquake by absorbing shock through devices like friction pendulums and elastomeric bearings. There are various types of base isolators including low-damping rubber bearings, lead-rubber bearings, and sliding systems. Base isolation is most suitable for low to medium-rise buildings founded on firm soil, as it reduces seismic forces and prevents damage by permitting the ground and structure to move independently.
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The document discusses base isolation as an earthquake protection system. It begins with an introduction to earthquakes and then defines base isolation as a system that uses flexible interfaces between a structure and its foundation to decouple the structure from ground motions during an earthquake. It describes various types of base isolation systems, including sliding and elastomeric bearing systems, and discusses considerations for implementing base isolation for structures. It provides an example of base isolation being used in a new hospital built after the collapse of a hospital during an earthquake in India.
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Shear wall
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This document discusses guidelines for constructing earthquake resistant masonry buildings. It begins by defining earthquakes and outlining key precautions in planning like ensuring buildings are light, symmetrical, regular, and simple in design. It then discusses failure mechanisms of masonry structures, including out-of-plane failure and connection failure. The document provides suggestions for new masonry buildings in seismic areas, such as using quality materials, limiting building size and height, and reinforcing wall connections.
Basics of earthquake & structural and non structural guidelines for building ...
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The presentation covers the scenario post a hazard of Earthquake turned into a disaster. Further, it includes the basic terminology, dynamics of EQ event, and suggests remedial practices for structural and non-structural elements of a building. Purpose the compilation is to sensitize learners.Shear wall
Shear wallFinal year Btech civil engineering student at viswajyothi college of engineering & technology
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This document summarizes earthquake resistant techniques. It discusses conventional methods like strengthening buildings through stiffness and ductility. Advanced methods of base isolation and energy dissipation devices are explained. Case studies on buildings like Torre Mayor and Transamerica Pyramid are provided. Techniques under research like shape memory alloys, mussel fibers, visco-elastic dampers and rubber cloaking are outlined. Seismic zones and codes in India are briefly covered along with references.
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The document discusses reasons why reinforced concrete (RC) structures fail during earthquakes and measures to improve their performance. Key points include:
1) RC buildings often fail due to design deficiencies like ignoring concepts of strong columns-weak beams or having soft stories, or construction defects like weak joints or improper reinforcement detailing.
2) Measures to improve performance include following design concepts of strong columns-weak beams and designing soft story elements to withstand higher forces, as well as improving construction quality of joints and reinforcement details.
3) Other factors that can lead to failure are short column effects, torsional forces from asymmetric shapes, and disturbance of the load path through the structure.
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This document discusses techniques for earthquake resistance in buildings. It begins by defining earthquakes and their effects. Common techniques for earthquake resistance discussed include shear walls, bracing, dampers, rollers, base isolation, and use of light materials. Frame types used in construction that can resist earthquakes are also examined. Suggestions are provided such as avoiding weak columns, providing thick slabs and cross walls, and using symmetrical building shapes and reinforcement. Popular techniques for earthquake resistant design discussed are base isolation devices and seismic dampers.
Earthquake resistance buildings
The document discusses earthquake resistant structures. It begins by defining what an earthquake is and explaining that they are caused by a sudden release of energy in the earth's crust that creates seismic waves. Earthquakes can range from minor shakes that are barely felt to violent shakes that cause widespread destruction. The document then discusses different types of seismic waves like P waves, S waves, and surface waves. It also covers earthquake terminology like focus, epicenter, and fault lines. The rest of the document discusses factors that affect earthquake damage, different types of faults, and design considerations for earthquake resistant structures.
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The document provides an overview of seismology and earthquake-resistant building planning. It discusses key topics such as:
1) Seismology is defined as the science of earthquakes and elastic waves.
2) The internal structure of the Earth consists of a crust, mantle, outer core, and inner core. Convective currents in the mantle cause tectonic plates to move.
3) Earthquakes are caused by the buildup and sudden release of stresses along fault lines within the Earth. Different types of boundaries exist between tectonic plates.
4) Important considerations for making buildings earthquake resistant include having a regular configuration, ductile elements, quality control measures, and potentially using base isolation
Different types of damages that have been observed in masonry buildings durin...
The document summarizes different types of damages observed in masonry buildings during past earthquakes outside and inside India. For earthquakes outside India, it describes damages like through diagonal cracks or X-shaped cracks on walls, horizontal cracks on walls and bearing brick columns, severe damage to stair parts, and damage to non-structural components like parapets and corridor fences. It also discusses damages caused by structural irregularities. For earthquakes in India, it lists failure patterns of masonry structures under categories such as out-of-plane flexural failure, in-plane shear failure, separation of walls at junctions, corner separations, failure of masonry piers, and collapse of wythes.
EARTHQUAKE-RESISTENT-BUILDING-CONSTRUCTION-ppt.pptx
Earthquake resistant building is an important for livelihood .To overcome the problem of earthquakes,it is necessary to find the methods of resisting of Earthquakes.so it provides better livelihood for people and lives
EARTHQUAKE-RESISTENT-BUILDING-CONSTRUCTION-ppt.pptx
This document discusses various techniques for constructing earthquake resistant buildings. It explains how earthquake resistant construction differs from traditional building by designing for large seismic forces. It describes the effects of earthquakes on reinforced concrete structures and discusses the seismic design philosophy of allowing damage from minor quakes while preventing collapse during major quakes. The document also summarizes several earthquake resistant construction methods including using reinforced hollow concrete blocks, mid-level isolation, slurry infiltrated mat concrete, and traditional earthquake resistant housing techniques. It concludes by stressing the need for better earthquake disaster mitigation through awareness, avoidance of non-engineered structures, and updated building codes.
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Base isolation
Base isolation is a seismic protection system that separates a structure from its foundation, allowing the structure to remain largely motionless during an earthquake by absorbing shock through devices like friction pendulums and elastomeric bearings. There are various types of base isolators including low-damping rubber bearings, lead-rubber bearings, and sliding systems. Base isolation is most suitable for low to medium-rise buildings founded on firm soil, as it reduces seismic forces and prevents damage by permitting the ground and structure to move independently.
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The document describes the seismic analysis and design of a multistoried reinforced concrete building. It discusses the objectives, background, literature review, methodology, and concepts for reducing earthquake effects. The methodology section explains the functional and structural planning, load assessment including gravity and lateral loads, preliminary design of structural elements like slabs, beams and columns. It also discusses drift calculation and load path. The design and detailing section provides details on the design of structural components like slab, beam, column, staircase, footing and basement wall based on Indian codes.
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The document discusses base isolation as an earthquake protection system. It begins with an introduction to earthquakes and then defines base isolation as a system that uses flexible interfaces between a structure and its foundation to decouple the structure from ground motions during an earthquake. It describes various types of base isolation systems, including sliding and elastomeric bearing systems, and discusses considerations for implementing base isolation for structures. It provides an example of base isolation being used in a new hospital built after the collapse of a hospital during an earthquake in India.
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A shear wall is a vertical structural element used to resist horizontal forces such as wind and seismic forces. Shear walls are generally used in high-rise buildings where the effects of wind and seismic forces are more significant. Shear walls are usually provided along both the length and width of buildings and act like vertically-oriented beams that carry earthquake loads downwards to the foundation. Common types of shear walls include reinforced concrete, concrete block, steel, plywood, and mid-ply shear walls. Shear walls must provide the necessary lateral strength to resist horizontal earthquake forces and lateral stiffness to prevent excessive side-sway of the structure.
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Its will be ensure that to interact with new technique to reduce from effect on building by Earthquake
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This document discusses techniques for building earthquake resistant structures in India. It covers various sources of earthquakes and methods to resist seismic activity, including both active and passive systems. Some specific techniques mentioned are shear walls, bracing, dampers, isolation, and using light-weight materials. Suggestions are provided such as avoiding weak column designs, including thick slabs and cross walls, and following building codes.
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The document discusses reasons why reinforced concrete (RC) structures fail during earthquakes and measures to improve their performance. Key points include:
1) RC buildings often fail due to design deficiencies like ignoring concepts of strong columns-weak beams or having soft stories, or construction defects like weak joints or improper reinforcement detailing.
2) Measures to improve performance include following design concepts of strong columns-weak beams and designing soft story elements to withstand higher forces, as well as improving construction quality of joints and reinforcement details.
3) Other factors that can lead to failure are short column effects, torsional forces from asymmetric shapes, and disturbance of the load path through the structure.
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This document discusses reinforced concrete shear walls. It provides definitions, design considerations, placement guidelines, and seismic behavior analysis. Shear walls are designed to resist lateral forces from earthquakes by providing strength, stiffness, and minimizing structural sway. Case studies demonstrate that high axial load ratios decrease ductility, and shear walls with staggered openings perform better seismically than those with regular openings.
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- Design considerations and different techniques employed to resist building from collapse during earthquake
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This document discusses techniques for earthquake resistance in buildings. It begins by defining earthquakes and their effects. Common techniques for earthquake resistance discussed include shear walls, bracing, dampers, rollers, base isolation, and use of light materials. Frame types used in construction that can resist earthquakes are also examined. Suggestions are provided such as avoiding weak columns, providing thick slabs and cross walls, and using symmetrical building shapes and reinforcement. Popular techniques for earthquake resistant design discussed are base isolation devices and seismic dampers.
Earthquake resistance buildings
The document discusses earthquake resistant structures. It begins by defining what an earthquake is and explaining that they are caused by a sudden release of energy in the earth's crust that creates seismic waves. Earthquakes can range from minor shakes that are barely felt to violent shakes that cause widespread destruction. The document then discusses different types of seismic waves like P waves, S waves, and surface waves. It also covers earthquake terminology like focus, epicenter, and fault lines. The rest of the document discusses factors that affect earthquake damage, different types of faults, and design considerations for earthquake resistant structures.
Earthquake Resistance planning
The document provides an overview of seismology and earthquake-resistant building planning. It discusses key topics such as:
1) Seismology is defined as the science of earthquakes and elastic waves.
2) The internal structure of the Earth consists of a crust, mantle, outer core, and inner core. Convective currents in the mantle cause tectonic plates to move.
3) Earthquakes are caused by the buildup and sudden release of stresses along fault lines within the Earth. Different types of boundaries exist between tectonic plates.
4) Important considerations for making buildings earthquake resistant include having a regular configuration, ductile elements, quality control measures, and potentially using base isolation
Different types of damages that have been observed in masonry buildings durin...
The document summarizes different types of damages observed in masonry buildings during past earthquakes outside and inside India. For earthquakes outside India, it describes damages like through diagonal cracks or X-shaped cracks on walls, horizontal cracks on walls and bearing brick columns, severe damage to stair parts, and damage to non-structural components like parapets and corridor fences. It also discusses damages caused by structural irregularities. For earthquakes in India, it lists failure patterns of masonry structures under categories such as out-of-plane flexural failure, in-plane shear failure, separation of walls at junctions, corner separations, failure of masonry piers, and collapse of wythes.
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Earthquake resistant analysis and design of multistoried building
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This document provides information on earthquake resistant building designs. It discusses what earthquakes are, why they are deadly, India's earthquake risk profile, and the need for earthquake resistant design. Some important considerations for design include configuration, ductility, quality control, base isolation, passive energy dissipating devices, and active control systems. Historical examples of seismic vibration control techniques are also presented, such as dry stone walls and base isolators.
MAJOR PROJECT menu.pptx
This document summarizes a student project on seismic retrofitting of buildings in Sikkim, India. The project aims to make existing buildings more earthquake resistant by modifying structural components and strengthening materials. Several retrofitting techniques are described, including reinforcement concrete jacketing, steel jacketing, steel caging, crack stitching, grouting, and shotcreting. The objectives are to prevent building collapse and loss of life during earthquakes by upgrading buildings to withstand seismic forces. The conclusion is that retrofitting provides sufficient strengthening to reduce earthquake damage to structures.
MAJOR PROJECT menu.pptx
This document presents a major project on seismic retrofitting of building structures in Sikkim. The project is submitted by 7 students and aims to make buildings earthquake resistant through retrofitting. It provides background on the 2011 Sikkim earthquake and introduces various retrofitting techniques like reinforcement concrete jacketing, steel jacketing, steel caging, crack stitching, grouting, and shotcreting. The objective is to modify existing structures to protect them from earthquake damage and reduce risks to lives. In conclusion, retrofitting can significantly improve a building's seismic performance and provide sufficient protection.
Aryyaka Sarkar 16011723001 Seminar on Earthquake Resistant Structures 23-24.pptx
This document summarizes information about earthquakes and earthquake-resistant building techniques. It defines an earthquake as the sudden release of strain energy in the Earth's crust. It describes the two main types of earthquakes and explains how they occur due to the movement of tectonic plates. It also discusses seismic waves, the causes and effects of earthquakes, and techniques for improving earthquake resistance in buildings, such as using shear walls, base isolation, energy dissipation devices, and designs that keep buildings upright. The document emphasizes that earthquakes don't kill people directly, but rather damage to poorly designed structures can cause loss of life. It concludes that while earthquakes are inevitable, disasters can be prevented through safer building designs and construction practices.
Analysis of Seismic Performance of Rock Block Structures with STAAD Pro
From olden days until now in our construction filed unreinforced masonry blocks of rocks is used as foundation and super structure wall as load bearing structure. In which blocks are stacked, sometimes being mortared with various cements. Ancient civilizations used locally available rocks and cements to construct rock block columns, walls and edifices for residences, temples, fortifications and infrastructure. Monuments still exist as testaments to the high quality construction by historic cultures, despite the seismic and other potentially damaging geo-mechanical disturbances that threaten them. Conceptual failure modes under seismic conditions of rock block structures, observed in the field or the laboratory, are presented. Our proposed work is analytically is carried out with rock block of 1m by 1m with 200 mm rock block under seismic loading to find out the damaged caused by the Mw 6.7 and 6.0 earthquakes on that block subject to dynamic load. Finally graphical output has generated and suggested for safe construction with more seismic load on rock blocks.
Research study on Soil Structure Interaction of Integrated Earth Retaining Wa...
This document summarizes research on soil-structure interaction of integrated earth retaining walls. It discusses how precast concrete retaining walls can be constructed more quickly and cost effectively using interlocking blocks with mortar-less joints. The research aims to analyze such integrated retaining walls and evaluate their strength and deformation under lateral soil pressures through modeling in ANSYS software. Prior studies on precast retaining walls, soil-structure interaction, and use of relief shelves to increase wall stability are also reviewed.
seismicretrofitting of existing structure
1. The document discusses techniques for seismic retrofitting of existing structures, including adding new shear walls, steel bracing, jacketing columns and beams, using innovative materials like FRP composites, base isolation, seismic dampers, and tuned mass dampers.
2. It provides an overview of when seismic retrofitting is needed and objectives like ensuring public safety or maintaining structure functionality.
3. A case study describes retrofitting a historic structure in India damaged in an earthquake, including adding diagonal bracing, shotcreting walls, and cross pinning wall corners.
Oxala school of plastic arts
This document summarizes a school of plastic arts project in Oxaca, Mexico designed by architect Mauricio Rocha. The school buildings use rammed earth construction, mixing local soil with 15% cement to form thick load-bearing walls. The complex is arranged like a chessboard with individual art studio volumes interspersed with courtyards, creating changing pathways and views. The rammed earth walls give the buildings a sturdy, grounded quality suited to the local climate and materials.
Earthquake resistant structure By Engr. Ghulam Yasin Taunsvi
The resistance structure is structures designed to withstand earthquakes. While no structure can be entirely immune to damage from earthquakes, the goal of earthquake-resistant construction is to erect structures that fare better during seismic activity than their conventional counterparts.
Earthquake resistant architecture
for architecture students
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Shear wall
Reinforced concrete buildings in seismic regions often include vertical shear walls that run from the foundation to the roof. Shear walls help buildings withstand earthquakes by carrying lateral forces down to the foundation. They perform much better when properly designed with features like symmetrical placement, ductile reinforcement, and thickened boundary elements at the ends that experience high stresses. Buildings with sufficient shear walls have shown good performance during past earthquakes, making shear wall construction a popular approach in seismic design.
Presentation on earthquake resistance massonary structure
This presentation discusses how to make masonry structures more resistant to earthquakes. It defines earthquake resistant masonry structures as those built from brick, stone or other masonry materials combined with containment reinforcement. It describes stresses in masonry walls during quakes and modeling of walls, then discusses techniques to strengthen buildings like adding flexibility, reinforcing walls and foundations, and containment reinforcement around walls. Shock table testing was also used to evaluate different earthquake resistant building features in masonry models.
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Earthquake Resistant designs with exp... all the things u need to know
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Aryyaka Sarkar 16011723001 Seminar on Earthquake Resistant Structures 23-24.pptx
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More from seminarppts
DISASTER MANAGEMENT
Disaster Management refers to manage disaster response in the country. India has been traditionally vulnerable to the natural disasters on the account of its unique geo-climatic conditions. Floods, droughts, cyclones, earthquakes and landslides would have been a recurrent phenomena. About 60% of the landmass is prone to earthquakes of various intensities; over 40 million hectares is prone to floods; about 8% of the total area is prone to cyclones and 68% of the area is susceptible to drought. In the decade 1990-2000, an average of about 4344 people lost their lives and about 30 million people were affected by disasters every year.
The loss in terms of private, community and public assets has been astronomical.At the global level, there has been considerable concern over natural disasters. Even as substantial scientific and material progress is made, the loss of lives and property due to disasters has not decreased. In fact, the human toll and economic losses have mounted up. It was in this background that the United Nations General Assembly, in 1989, declared the decade 1990-2000 as the International Decade for Natural Disaster Reduction with the objective to reduce loss of lives and property and restrict socio-economic damage through concerted international action, was specially certified in developing countries.
The super cyclone in Orissa in October, 1999 and the Bhuj earthquake in Gujarat in January, 2001 underscored the need to adopt a multi dimensional endeavour involving diverse scientific, engineering, financial and social processes; the need to adopt multi disciplinary and multi sectoral approach and incorporation of risk reduction in the developmental plans and strategies.
FIBER REINFORCED CONCRETE
Fibers are usually used in concrete to control cracking due to plastic shrinkage and to drying shrinkage. They also reduce the permeability of concrete and thus reduce bleeding of water. Some types of fibers produce greater impact–, abrasion–, and shatter–resistance in concrete. Generally fibers do not increase the flexural strength of concrete, and so cannot replace moment–resisting or structural steel reinforcement. Indeed, some fibers actually reduce the strength of concrete.
The amount of fibers added to a concrete mix is expressed as a percentage of the total volume of the composite (concrete and fibers), termed "volume fraction" (Vf). Vf typically ranges from 0.1 to 3%. The aspect ratio (l/d) is calculated by dividing fiber length (l) by its diameter (d). Fibers with a non-circular cross section use an equivalent diameter for the calculation of aspect ratio. If the fiber's modulus of elasticity is higher than the matrix (concrete or mortar binder), they help to carry the load by increasing the tensile strength of the material. Increasing the aspect ratio of the fiber usually segments the flexural strength and toughness of the matrix. However, fibers that are too long tend to "ball" in the mix and create workability problems.
Some recent research[where?] indicated that using fibers in concrete has limited effect on the impact resistance of the materials.[1][2] This finding is very important since traditionally, people think that ductility increases when concrete is reinforced with fibers. The results also indicated that the use of micro fibers offers better impact resistance to that of longer fibers.[1]
The High Speed 1 tunnel linings incorporated concrete containing 1 kg/m³ of polypropylene fibers, of diameter 18 & 32 μm, giving the benefits noted below.
BUILDING DEMOLITION
The document summarizes the process of demolishing a building. It discusses that demolition is necessary after a building reaches the end of its service life due to safety concerns. There are several steps taken before demolition, including surveying, removing hazardous materials, and developing a demolition plan and safety measures. Demolition can be done through non-explosive methods using equipment like sledgehammers, or through explosive demolition by strategically removing structural supports to bring the building down in a controlled manner. The type of demolition method depends on factors like the building's condition, size, and cost effectiveness.
NANO CONCRETE
Nanotechnology ("nanotech") is manipulation of matter on an atomic, molecular, and supramolecular scale. The earliest, widespread description of nanotechnology[1][2] referred to the particular technological goal of precisely manipulating atoms and molecules for fabrication of macroscale products, also now referred to as molecular nanotechnology. A more generalized description of nanotechnology was subsequently established by the National Nanotechnology Initiative, which defines nanotechnology as the manipulation of matter with at least one dimension sized from 1 to 100 nanometers. This definition reflects the fact that quantum mechanical effects are important at this quantum-realm scale, and so the definition shifted from a particular technological goal to a research category inclusive of all types of research and technologies that deal with the special properties of matter which occur below the given size threshold. It is therefore common to see the plural form "nanotechnologies" as well as "nanoscale technologies" to refer to the broad range of research and applications whose common trait is size. Because of the variety of potential applications (including industrial and military), governments have invested billions of dollars in nanotechnology research. Through 2012, the USA has invested $3.7 billion using its National Nanotechnology Initiative, the European Union has invested $1.2 billion, and Japan has invested $750 million.[3]
Nanotechnology as defined by size is naturally very broad, including fields of science as diverse as surface science, organic chemistry, molecular biology, semiconductor physics, energy storage,[4][5] microfabrication,[6] molecular engineering, etc.[7] The associated research and applications are equally diverse, ranging from extensions of conventional device physics to completely new approaches based upon molecular self-assembly,[8] from developing new materials with dimensions on the nanoscale to direct control of matter on the atomic scale.
Scientists currently debate the future implications of nanotechnology. Nanotechnology may be able to create many new materials and devices with a vast range of applications, such as in nanomedicine, nanoelectronics, biomaterials energy production, and consumer products. On the other hand, nanotechnology raises many of the same issues as any new technology, including concerns about the toxicity and environmental impact of nanomaterials,[9] and their potential effects on global economics, as well as speculation about various doomsday scenarios. These concerns have led to a debate among advocacy groups and governments on whether special regulation of nanotechnology is warranted.
STRESS RIBBON BRIDGE
Suspension bridges are suspended from cables. The earliest suspension bridges were made of ropes or vines covered with pieces of bamboo. In modern bridges, the cables hang from towers that are attached to caissons or cofferdams. The caissons or cofferdams are implanted deep into the bed of the lake, river or sea. Sub-types include the simple suspension bridge, the stressed ribbon bridge, the underspanned suspension bridge, the suspended-deck suspension bridge, and the self-anchored suspension bridge. There is also what is sometimes called a "semi-suspension" bridge, of which the Ferry Bridge in Burton-upon-Trent is the only one of its kind in Europe.[19]
The longest suspension bridge in the world is the 3,909 m (12,825 ft) Akashi Kaikyō Bridge in Japan.
BAMBOO AS A BUILDING MATERIAL
In its natural form, bamboo as a construction material is traditionally associated with the cultures of South Asia, East Asia and the South Pacific, to some extent in Central and South America, and by extension in the aesthetic of Tiki culture. In China and India, bamboo was used to hold up simple suspension bridges, either by making cables of split bamboo or twisting whole culms of sufficiently pliable bamboo together. One such bridge in the area of Qian-Xian is referenced in writings dating back to 960 AD and may have stood since as far back as the third century BC, due largely to continuous maintenance.
Bamboo has also long been used as scaffolding; the practice has been banned in China for buildings over six stories, but is still in continuous use for skyscrapers in Hong Kong.[6] In the Philippines, the nipa hut is a fairly typical example of the most basic sort of housing where bamboo is used; the walls are split and woven bamboo, and bamboo slats and poles may be used as its support. In Japanese architecture, bamboo is used primarily as a supplemental and/or decorative element in buildings such as fencing, fountains, grates and gutters, largely due to the ready abundance of quality timber.
GREEN BUILDINGS
Green building (also known as green construction or sustainable building) refers to both a structure and the application of processes that are environmentally responsible and resource-efficient throughout a building's life-cycle: from planning to design, construction, operation, maintenance, renovation, and demolition.[1] This requires close cooperation of the contractor, the architects, the engineers, and the client at all project stages.[2] The Green Building practice expands and complements the classical building design concerns of economy, utility, durability, and comfort.[3]
Leadership in Energy and Environmental Design (LEED) is a set of rating systems for the design, construction, operation, and maintenance of green buildings which was Developed by the U.S. Green Building Council. Other certificates system that confirms the sustainability of buildings is the British BREEAM (Building Research Establishment Environmental Assessment Method) for buildings and large-scale developments. Currently, World Green Building Council is conducting research on the effects of green buildings on the health and productivity of their users and is working with World Bank to promote Green Buildings in Emerging Markets through EDGE (Excellence in Design for Greater Efficiencies) Market Transformation Program and certification.[4] There are also other tools such as Green Star in Australia and the Green Building Index (GBI) predominantly used in Malaysia.
Although new technologies are constantly being developed to complement current practices in creating greener structures, the common objective of green buildings is to reduce the overall impact of the built environment on human health and the natural environment by:
Efficiently using energy, water, and other resources
Protecting occupant health and improving employee productivity
Reducing waste, pollution and environmental degradation
SUBMERGED FLOATING TUNNEL
The concept of submerged floating tunnels is based on well-known technology applied to floating bridges and offshore structures, but the construction is mostly similar to that of immersed tunnels: One way is to build the tube in sections in a dry dock; then float these to the construction site and sink them into place, while sealed; and, when the sections are fixed to each other, the seals are broken. Another possibility is to build the sections unsealed, and after welding them together, pump the water out.
The ballast used is calculated so that the structure has approximate hydrostatic equilibrium (that is, the tunnel is roughly the same overall density as water), whereas immersed tube tunnels are ballasted more to weight them down to the sea bed. This, of course, means that a submerged floating tunnel must be anchored to the ground or to the water surface to keep it in place (which of these depends on which side of the equilibrium point the tunnel is)
SHOTCRETE TECHNOLOGY
Shotcrete or sprayed concrete (Gunite®) is concrete or mortar conveyed through a hose and pneumatically projected at high velocity onto a surface, as a construction technique. It is typically reinforced by conventional steel rods, steel mesh, or fibers.
Shotcrete is usually an all-inclusive term for both the wet-mix and dry-mix versions. In pool construction, however, shotcrete refers to wet mix and gunite to dry mix. In this context, these terms are not interchangeable.
Shotcrete is placed and compacted at the same time, due to the force with the nozzle. It can be sprayed onto any type or shape of surface, including vertical or overhead areas.
SANITATION
Sanitation refers to public health conditions related to clean drinking water and adequate treatment and disposal of human excreta and sewage.[1] Preventing human contact with feces is part of sanitation, as is hand washing with soap. Sanitation system aim to protect human health by providing a clean environment that will stop the transmission of disease, especially through the fecal-oral route.[2] For example, diarrhea, a main cause of malnutrition and stunted growth in children, can be reduced through sanitation.[3] There are many other diseases which are easily transmitted in communities that have low levels of sanitation, such as ascariasis (a type of intestinal worm infection or helminthiasis), cholera, hepatitis, polio, schistosomiasis, trachoma, to name just a few.
A range of sanitation technologies and approaches exists. Some examples are community-led total sanitation, container-based sanitation, ecological sanitation, emergency sanitation, environmental sanitation, onsite sanitation and sustainable sanitation. A sanitation system includes the capture, storage, transport, treatment and disposal or reuse of human excreta and wastewater.[4] Reuse activities within the sanitation system may focus on the nutrients, water, energy or organic matter contained in excreta and wastewater. This is referred to as the "sanitation value chain" or "sanitation economy
UNDER WATER CONCRETING
For dam construction, two cofferdams are usually built, one upstream and one downstream of the proposed dam, after an alternative diversion tunnel or channel has been provided for the river flow to bypass the dam foundation area. These cofferdams are typically a conventional embankment dam of both earth- and rock-fill, but concrete or some sheet piling also may be used. Typically, upon completion of the dam and associated structures, the downstream coffer is removed and the upstream coffer is flooded as the diversion is closed and the reservoir begins to fill. Dependent upon the geography of a dam site, in some applications, a "U"-shaped cofferdam is used in the construction of one half of a dam. When complete, the cofferdam is removed and a similar one is created on the opposite side of the river for the construction of the dam's other half.
The cofferdam is also used on occasion in the shipbuilding and ship repair industry, when it is not practical to put a ship in drydock for repair or alteration. An example of such an application is certain ship lengthening operations. In some cases a ship is actually cut in two while still in the water, and a new section of ship is floated in to lengthen the ship. Torch cutting of the hull is done inside a cofferdam attached directly to the hull of the ship; the cofferdam is then detached before the hull sections are floated apart. The cofferdam is later replaced while the hull sections are welded together again. As expensive as this may be to accomplish, use of a drydock may be even more expensive. See also caisson.
A 100-ton open caisson that was lowered more than a mile to the sea floor in attempts to stop the flow of oil in the Deepwater Horizon oil spill has been called a cofferdam.[4] It did not work, as methane hydrates froze in the upper levels preventing the containment.
SOLID WASTE MANGEMENT
Waste management or waste disposal are all the activities and actions required to manage waste from its inception to its final disposal.[1] This includes amongst other things collection, transport, treatment and disposal of waste together with monitoring and regulation. It also encompasses the legal and regulatory framework that relates to waste management encompassing guidance on recycling.
Waste can take any form that is solid, liquid, or gas and each have different methods of disposal and management. Waste management normally deals with all types of waste whether it was created in forms that are industrial, biological, household, and special cases where it may pose a threat to human health.[2] It is produced due to human activity such as when factories extract and process raw materials.[3] Waste management is intended to reduce adverse effects of waste on health, the environment or aesthetics.
Waste management practices are not uniform among countries (developed and developing nations); regions (urban and rural areas), and sectors (residential and industrial).[4]
A large portion of waste management practices deal with municipal solid waste (MSW) which is waste that is created by household, industrial, and commercial activity.[5]
BUBBLE DECK SLAB
A concrete slab is a common structural element of modern buildings. Horizontal slabs of steel reinforced concrete, typically between 4 and 20 inches (100 and 500 millimeters) thick, are most often used to construct floors and ceilings, while thinner slabs are also used for exterior paving. Sometimes these thinner slabs, ranging from 2 inches (51 mm) to 6 inches (150 mm) thick, are called mud slabs, particularly when used under the main floor slabs[1] or in crawl spaces.[2]
In many domestic and industrial buildings a thick concrete slab, supported on foundations or directly on the subsoil, is used to construct the ground floor of a building. These can either be "ground-bearing" or "suspended" slabs. The slab is "ground-bearing" if it rests directly on the foundation, otherwise the slab is "suspended".[3] For double-storey or multi-storey buildings, the use of a few common types of concrete suspended slabs are used (for more types refer to the Concrete Slab#Design section below):
Beam and block also referred to as Rib and Block, are mostly used in residential and industrial applications. This slab type is made up of pre-stressed beams and hollow blocks and are temporarily propped until set, typically after 21 days.
A Hollow core slab which are precast and installed on site with a crane.
In high rise buildings and skyscrapers, thinner, pre-cast concrete slabs are slung between the steel frames to form the floors and ceilings on each level. Cast in-situ slabs are used in high rise buildings and huge shopping complexes as well as houses. These in-situ slabs are cast on site using shutters and reinforced steel.
RECYCLED AGGREGATES
The largest-volume of recycled material used as construction aggregate is blast furnace and steel furnace slag. Blast furnace slag is either air-cooled (slow cooling in the open) or granulated (formed by quenching molten slag in water to form sand-sized glass-like particles). If the granulated blast furnace slag accesses free lime during hydration, it develops strong hydraulic cementitious properties and can partly substitute for portland cement in concrete. Steel furnace slag is also air-cooled. In 2006, according to the USGS, air-cooled blast furnace slag sold or used in the U.S. was 7.3 million tonnes valued at $49 million, granulated blast furnace slag sold or used in the U.S. was 4.2 million tonnes valued at $318 million, and steel furnace slag sold or used in the U.S. was 8.7 million tonnes valued at $40 million. Air-cooled blast furnace slag sales in 2006 were for use in road bases and surfaces (41%), asphaltic concrete (13%), ready-mixed concrete (16%), and the balance for other uses. Granulated blast furnace slag sales in 2006 were for use in cementitious materials (94%), and the balance for other uses. Steel furnace slag sales in 2006 were for use in road bases and surfaces (51%), asphaltic concrete (12%), for fill (18%), and the balance for other uses
CERAMIC WASTE CONCRETE
A ceramic is an inorganic compound, non-metallic, solid material comprising metal, non-metal or metalloid atoms primarily held in ionic and covalent bonds. This article gives an overview of ceramic materials from the point of view of materials science.
The crystallinity of ceramic materials ranges from highly oriented to semi-crystalline, vitrified, and often completely amorphous (e.g., glasses). Most often, fired ceramics are either vitrified or semi-vitrified as is the case with earthenware, stoneware, and porcelain. Varying crystallinity and electron consumption in the ionic and covalent bonds cause most ceramic materials to be good thermal and electrical insulators (extensively researched in ceramic engineering). With such a large range of possible options for the composition/structure of a ceramic (e.g. nearly all of the elements, nearly all types of bonding, and all levels of crystallinity), the breadth of the subject is vast, and identifiable attributes (e.g. hardness, toughness, electrical conductivity, etc.) are hard to specify for the group as a whole. General properties such as high melting temperature, high hardness, poor conductivity, high moduli of elasticity, chemical resistance and low ductility are the norm,[1] with known exceptions to each of these rules (e.g. piezoelectric ceramics, glass transition temperature, superconductive ceramics, etc.). Many composites, such as fiberglass and carbon fiber, while containing ceramic materials, are not considered to be part of the ceramic family.[2]
HIGHWAY NETWORK SYSTEM
A highway is any public or private road or other public way on land. It is used for major roads, but also includes other public roads and public tracks: It is not an equivalent term to controlled-access highway, or a translation for autobahn, autoroute, etc.
In North American and Australian English, major roads such as controlled-access highways or arterial roads are often state highways (Canada: provincial highways). Other roads may be designated "county highways" in the US and Ontario. These classifications refer to the level of government (state, provincial, county) that maintains the roadway.
In British English, "highway" is primarily a legal term. Everyday use normally implies roads, while the legal use covers any route or path with a public right of access, including footpaths etc.
The term has led to several related derived terms, including highway system, highway code, highway patrol and highwayman.
The term highway exists in distinction to "waterway".
HIGH PERFORMANCE CONCRETE
High-performance fiber-reinforced cementitious composites (HPFRCCs) are a group of fiber-reinforced cement-based composites which possess the unique ability to flex and self-strengthen before fracturing. This particular class of concrete was developed with the goal of solving the structural problems inherent with today’s typical concrete, such as its tendency to fail in a brittle manner under excessive loading and its lack of long-term durability. Because of their design and composition, HPFRCCs possess the remarkable ability to strain harden under excessive loading. In layman’s terms, this means they have the ability to flex or deform before fracturing, a behavior similar to that exhibited by most metals under tensile or bending stresses. Because of this capability, HPFRCCs are more resistant to cracking and last considerably longer than normal concrete. Another extremely desirable property of HPFRCCs is their low density. A less dense, and hence lighter material means that HPFRCCs could eventually require much less energy to produce and handle, deeming them a more economic building material. Because of HPFRCCs’ lightweight composition and ability to strain harden, it has been proposed that they could eventually become a more durable and efficient alternative to typical concrete.
HPFRCCs are simply a subcategory of ductile fiber-reinforced cementititous composites (DFRCCs) that possess the ability to strain harden under both bending and tensile loads, not to be confused with other DFRCCs that only strain harden under bending loads.
WATERCYCLE
The water cycle, also known as the hydrological cycle or the hydrologic cycle, describes the continuous movement of water on, above and below the surface of the Earth. The mass of water on Earth remains fairly constant over time but the partitioning of the water into the major reservoirs of ice, fresh water, saline water and atmospheric water is variable depending on a wide range of climatic variables. The water moves from one reservoir to another, such as from river to ocean, or from the ocean to the atmosphere, by the physical processes of evaporation, condensation, precipitation, infiltration, surface runoff, and subsurface flow. In doing so, the water goes through different forms: liquid, solid (ice) and vapor.
The water cycle involves the exchange of energy, which leads to temperature changes. When water evaporates, it takes up energy from its surroundings and cools the environment. When it condenses, it releases energy and warms the environment. These heat exchanges influence climate.
The evaporative phase of the cycle purifies water which then replenishes the land with freshwater. The flow of liquid water and ice transports minerals across the globe. It is also involved in reshaping the geological features of the Earth, through processes including erosion and sedimentation. The water cycle is also essential for the maintenance of most life and ecosystems on the planet.
Plastic bricks
A paving stone or brick made in any desired shape that can be used for pavements, building bricks or other purposes. these 'eco-friendly' paving bricks are cheaper than the classic model.
Paving stones can be manufactured from waste plastics without requiring significant capital investment. The main component of the mixture can be made from plastic packaging (like bags and transparent films) and it is possible to mix other types of plastic waste in. The process is simple, melting the plastics down and mixing with sand. This mixture can then be moulded into any desired shape to produce paving tiles (such as for pavements)
There are several steps to production. The plastic serves to bind the materials together. The plastic is then melted in a vat over a wood fire. You then add sand and mix it. Then, you pour the mix into a mould and let it dry for 15 minutes.
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rock mass characterization and New techniques for characterising damage in rock slopes
一比一原版(UC Berkeley毕业证)加利福尼亚大学|伯克利分校毕业证成绩单专业办理
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ACEP Magazine edition 4th launched on 05.06.2024
This document provides information about the third edition of the magazine "Sthapatya" published by the Association of Civil Engineers (Practicing) Aurangabad. It includes messages from current and past presidents of ACEP, memories and photos from past ACEP events, information on life time achievement awards given by ACEP, and a technical article on concrete maintenance, repairs and strengthening. The document highlights activities of ACEP and provides a technical educational article for members.
Design and Analysis of Algorithms-DP,Backtracking,Graphs,B&B
Dynamic Programming
Backtracking
Techniques for Graphs
Branch and Bound
Recycled Concrete Aggregate in Construction Part III
Using recycled concrete aggregates (RCA) for pavements is crucial to achieving sustainability. Implementing RCA for new pavement can minimize carbon footprint, conserve natural resources, reduce harmful emissions, and lower life cycle costs. Compared to natural aggregate (NA), RCA pavement has fewer comprehensive studies and sustainability assessments.
Harnessing WebAssembly for Real-time Stateless Streaming Pipelines
Traditionally, dealing with real-time data pipelines has involved significant overhead, even for straightforward tasks like data transformation or masking. However, in this talk, we’ll venture into the dynamic realm of WebAssembly (WASM) and discover how it can revolutionize the creation of stateless streaming pipelines within a Kafka (Redpanda) broker. These pipelines are adept at managing low-latency, high-data-volume scenarios.
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本公司拥有海外各大学样板无数,能完美还原海外各大学 Bachelor Diploma degree, Master Degree Diploma
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留信网认证的作用:
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2:同时对留学生所学专业登记给予评定
3:国家专业人才认证中心颁发入库证书
4:这个认证书并且可以归档倒地方
5:凡事获得留信网入网的信息将会逐步更新到个人身份内,将在公安局网内查询个人身份证信息后,同步读取人才网入库信息
6:个人职称评审加20分
7:个人信誉贷款加10分
8:在国家人才网主办的国家网络招聘大会中纳入资料,供国家高端企业选择人才
Adaptive synchronous sliding control for a robot manipulator based on neural ...
Robot manipulators have become important equipment in production lines, medical fields, and transportation. Improving the quality of trajectory tracking for
robot hands is always an attractive topic in the research community. This is a
challenging problem because robot manipulators are complex nonlinear systems
and are often subject to fluctuations in loads and external disturbances. This
article proposes an adaptive synchronous sliding control scheme to improve trajectory tracking performance for a robot manipulator. The proposed controller
ensures that the positions of the joints track the desired trajectory, synchronize
the errors, and significantly reduces chattering. First, the synchronous tracking
errors and synchronous sliding surfaces are presented. Second, the synchronous
tracking error dynamics are determined. Third, a robust adaptive control law is
designed,the unknown components of the model are estimated online by the neural network, and the parameters of the switching elements are selected by fuzzy
logic. The built algorithm ensures that the tracking and approximation errors
are ultimately uniformly bounded (UUB). Finally, the effectiveness of the constructed algorithm is demonstrated through simulation and experimental results.
Simulation and experimental results show that the proposed controller is effective with small synchronous tracking errors, and the chattering phenomenon is
significantly reduced.
KuberTENes Birthday Bash Guadalajara - K8sGPT first impressions
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EARTHQUAKE RESISTANT BUILDINGS
- 1. MEKAPATI RAJAMOHAN REDDY INSTITUTE OF TECHNOLOGY & SCIENCE TECHINICAL SEMINAR ON EARTH QUAKE RESISTANCE BUILDING CONSTRUCTION PRESENTED BY S.VASIM 14L41A0103
- 2. INTRODUCTION HOW EARTHQUAKE RESISTENT BUILDING IS DIFERENT? EFFECT OF EARTHQUAKE ON REINFORCED CONCRETE BUILDINGS SEISMIC DESIGN PHILOSOPHY REMEDIAL MEASURES TO MINIMISE THE LOSSES DUE TO EARTHQUAKES EARTHQUAKE RESISTANT BUILDING CONSTRUCTION WITH REINFORCED HOLLOW CONCRETE BLOCK (RHCBM) MID-LEVEL ISOLATION EARTHQUAKE RESISTANCE USING SLURRY INFILTRATED MAT CONCRETE (SIMCON) TRADITIONAL EARTHQUAKE RESISTANT HOUSING EXAMPLES OF EARTHQUAKE RESISTANCE BUILDINGS IN THE WORLD CONCLUSIONS REFERENCES
- 3. An earthquake is the vibration, sometimes violent to the earth’s surface that follows a release of energy in the earth’s crust. This energy can be generated by a sudden dislocation of segments of the crust, by a volcanic eruption or even by a manmade explosion. The dislocation of the crust causes most destructive earthquakes.
- 4. Since the magnitude of a future earthquake and shaking intensity expected at a particular site cannot be estimated with a reasonable accuracy, the seismic forces are difficult to quantify for the purposes of design. Further, the actual forces that can be generated in the structure during an earthquake are very large and designing the structure to respond elastically against these forces make it too expensive.
- 5. In recent times, reinforced concrete buildings have become common in India. A typical RC building is made of horizontal members (beams and slabs) and vertical members (columns and walls) and supported by foundations that rest on the ground. The system consisting of RC columns and connecting beams is called a RC frame.
- 6. Severity of ground shaking at a given location during earthquake can be minor, moderate and strong. Relatively speaking, minor shaking occurs frequently; moderate shaking occasionally and strong shaking rarely.
- 7. Building planning Foundation Provision of band Arches and domes Staircases
- 8. Reinforced hollow concrete blocks are designed both as load-bearing walls for gravity loads and also as shear walls for lateral seismic loads, to safely withstand the earthquakes. This structural system of construction is known as shear wall-diaphragm concept, which gives three-dimensional structural integrity for the buildings.
- 9. This includes mid-level isolation system installed while the buildings are still being used. This new method entails improving and classifying the columns on intermediate floors of an existing building into flexible columns that incorporate rubber bearings (base isolation systems) and rigid columns which have been wrapped in steel plates to add to their toughness.
- 10. Following the devastating earthquakes in Turkey this summer that killed as many as 20,000 people and injured another 27,000, images of survivors trapped beneath the rubble of collapsed buildings appeared daily in news reports worldwide. Now a North Carolina State University engineer is developing a new type of concrete to help prevent such scenes from happening again.
- 11. The Pherols of Uttarkashi The Dhajji-Diwari buildings of Kashmir The Kat-Ki- Kunni Buildings of Kulu Valley Quincha earthquake resistant buildings
- 12. Burz khalifa, UAE Shangai Tower, China
- 13. Twin towers, Kaulalampur, Malyasia Anitila house, Mumbai, India
- 14. There is a lack of awareness in the earthquake disaster mitigations. Avoiding non-engineered structures with unskilled labour even in unimportant temporary constructions can help a great way. Statewide awareness programmes have to be conducted by fully exploiting the advancement in the information technology. Urgent steps are required to be taken to make the codal provisions regarding earthquake resistant construction undebatable.
- 15. www.google.com www.wikipedia.com www.studymafia.org
- 17. ANY QUERIES?