A gravity dam is a solid structure, made of concrete or masonry, constructed across a river to create a reservoir on its
upstream. The section of the gravity dam is approximately triangular in shape, with its apex at its top and maximum width at bottom.
The section is so proportioned that it resists the various forces acting on it by its own weight. Most of the gravity dams are solid, so that
no bending stress is introduced at any point and hence, they are sometimes known as solid gravity dams to distinguish them from hollow
gravity dams in those hollow spaces are kept to reduce the weight. Early gravity dams were built of masonry, but now-a-days with
improved methods of construction, quality control and curing, concrete is most commonly used for the construction of modern gravity
dams.
This document provides information about forces acting on gravity dams. It discusses the main stabilizing and destabilizing forces, including the weight of the dam, water pressure on the upstream and downstream faces, uplift pressure, earth and silt pressures, ice pressure, and other loads. It defines key terms related to gravity dams such as structural height, base width, axis, and explains how to calculate the various forces per unit length of the dam. Uplift pressure is explained as being dependent on the permeability of the dam and foundation materials and effective drainage. Design criteria for calculating uplift forces according to Indian standards is also summarized.
This document discusses forces acting on concrete gravity dams, including uplift pressure. Uplift pressure is an important force to consider in gravity dam design and safety, as it can compromise structural integrity, especially in cracked dams. The document outlines the traditional approach to modeling uplift pressure as varying linearly from full reservoir pressure at the base upstream to zero pressure downstream. It notes that a more conservative modern approach is to apply uplift pressure across the full base area. Proper consideration of uplift pressure is crucial for gravity dam safety evaluations and design.
This document provides information about dams and reservoirs. It discusses how dams are constructed across rivers to store water in reservoirs. It describes the different types of dams including gravity dams, buttress dams, arch dams, earth fill dams, and rock fill dams. Key factors in selecting a dam site include the geology of the location, with competent bedrock and an absence of faults or weak zones being important. Dams must also be designed based on the orientation and dip of the underlying rock strata. Extensive exploratory investigations are required at potential dam sites to understand the subsurface geology and suitability for construction.
This document provides information about preliminary selection of dams for a class project. It includes the student's name and details, along with an introduction that defines a dam and lists their objectives. It then discusses different types of dams including earth, rock, concrete, gravity, arch, buttress, embankment, and composite dams. Key factors for investigating potential dam sites are outlined, including geology, hydrology, availability of construction materials, and reservoir characteristics. The roles of geological studies in assessing foundation stability, water tightness, and material availability are summarized. Different dam designs are suited to varying geological and site conditions.
This document provides an overview of the design and analysis of concrete gravity dams. It discusses the key components and layout of concrete gravity dams, as well as the design steps and expected loadings. The main loads considered include dead load, water pressure, uplift pressure, silt pressure, wave pressure, and earthquake loads. Formulas are provided for calculating each of these loads. The document also discusses factors like stability, stress analysis, and freeboard that are important considerations in the design of concrete gravity dams.
This document provides information on dams and reservoirs, including:
- Dams are barriers that obstruct water flow, often creating reservoirs. They come in many types defined by their material, structure, purpose, or height.
- Proper planning is required when selecting dam and reservoir sites, considering hydrological, geological, environmental, social, and economic factors.
- Thorough investigation of potential sites is necessary, including surveys of topography, surface and subsurface geology, and available construction materials.
- The document discusses various dam types and characteristics in detail. It also covers reservoir capacity determination and other aspects of planning reservoirs.
DAMS
Types of dams
Selection of dam sites
Geological characters for investigation
Selection of the dam type
Gravity dams
butress dams
embankment dams
arch dams
cupola dams
composite dams
Bhakra Dam
Mir Alam multi-arch dam
Idukki Dam
Tehri Dam
Ujani Dam or bhima dam
The Rion Antirion Bridge project involves constructing a 3 km long multi-cable stayed bridge across the Gulf of Corinth in western Greece. It will be one of the largest bridges of its type in the world. The project faces significant engineering challenges due to high seismic activity in the region, deep weak soil layers, and the potential for fault displacements. Sophisticated dynamic analyses and foundation designs were required to develop a structure that can withstand strong earthquakes while maintaining serviceability. The bridge design utilizes seismic isolation of the deck and innovative reinforced soil foundations to improve bearing capacity and control failure modes under high seismic loads.
This document provides information about forces acting on gravity dams. It discusses the main stabilizing and destabilizing forces, including the weight of the dam, water pressure on the upstream and downstream faces, uplift pressure, earth and silt pressures, ice pressure, and other loads. It defines key terms related to gravity dams such as structural height, base width, axis, and explains how to calculate the various forces per unit length of the dam. Uplift pressure is explained as being dependent on the permeability of the dam and foundation materials and effective drainage. Design criteria for calculating uplift forces according to Indian standards is also summarized.
This document discusses forces acting on concrete gravity dams, including uplift pressure. Uplift pressure is an important force to consider in gravity dam design and safety, as it can compromise structural integrity, especially in cracked dams. The document outlines the traditional approach to modeling uplift pressure as varying linearly from full reservoir pressure at the base upstream to zero pressure downstream. It notes that a more conservative modern approach is to apply uplift pressure across the full base area. Proper consideration of uplift pressure is crucial for gravity dam safety evaluations and design.
This document provides information about dams and reservoirs. It discusses how dams are constructed across rivers to store water in reservoirs. It describes the different types of dams including gravity dams, buttress dams, arch dams, earth fill dams, and rock fill dams. Key factors in selecting a dam site include the geology of the location, with competent bedrock and an absence of faults or weak zones being important. Dams must also be designed based on the orientation and dip of the underlying rock strata. Extensive exploratory investigations are required at potential dam sites to understand the subsurface geology and suitability for construction.
This document provides information about preliminary selection of dams for a class project. It includes the student's name and details, along with an introduction that defines a dam and lists their objectives. It then discusses different types of dams including earth, rock, concrete, gravity, arch, buttress, embankment, and composite dams. Key factors for investigating potential dam sites are outlined, including geology, hydrology, availability of construction materials, and reservoir characteristics. The roles of geological studies in assessing foundation stability, water tightness, and material availability are summarized. Different dam designs are suited to varying geological and site conditions.
This document provides an overview of the design and analysis of concrete gravity dams. It discusses the key components and layout of concrete gravity dams, as well as the design steps and expected loadings. The main loads considered include dead load, water pressure, uplift pressure, silt pressure, wave pressure, and earthquake loads. Formulas are provided for calculating each of these loads. The document also discusses factors like stability, stress analysis, and freeboard that are important considerations in the design of concrete gravity dams.
This document provides information on dams and reservoirs, including:
- Dams are barriers that obstruct water flow, often creating reservoirs. They come in many types defined by their material, structure, purpose, or height.
- Proper planning is required when selecting dam and reservoir sites, considering hydrological, geological, environmental, social, and economic factors.
- Thorough investigation of potential sites is necessary, including surveys of topography, surface and subsurface geology, and available construction materials.
- The document discusses various dam types and characteristics in detail. It also covers reservoir capacity determination and other aspects of planning reservoirs.
DAMS
Types of dams
Selection of dam sites
Geological characters for investigation
Selection of the dam type
Gravity dams
butress dams
embankment dams
arch dams
cupola dams
composite dams
Bhakra Dam
Mir Alam multi-arch dam
Idukki Dam
Tehri Dam
Ujani Dam or bhima dam
The Rion Antirion Bridge project involves constructing a 3 km long multi-cable stayed bridge across the Gulf of Corinth in western Greece. It will be one of the largest bridges of its type in the world. The project faces significant engineering challenges due to high seismic activity in the region, deep weak soil layers, and the potential for fault displacements. Sophisticated dynamic analyses and foundation designs were required to develop a structure that can withstand strong earthquakes while maintaining serviceability. The bridge design utilizes seismic isolation of the deck and innovative reinforced soil foundations to improve bearing capacity and control failure modes under high seismic loads.
This document discusses factors to consider for dam site selection and investigation. The key factors include:
1. Geological conditions of the proposed site, including rock type, structure, strength, porosity, and permeability, which can impact dam stability and water tightness.
2. Hydrological factors like stream flow, rainfall, and reservoir characteristics, which determine water availability and storage.
3. Access and availability of construction materials. Suitable rock or earth is needed for building the dam.
4. Environmental impacts must also be considered, such as effects on ecology, water quality, and local communities. A thorough investigation of all relevant geological, hydrological and environmental factors is needed to select the optimal dam site.
This document discusses gravity dams and earth dams. For gravity dams, it describes the typical cross-section and forces acting on the dam, including water pressure, dam weight, uplift pressure, and more. It also discusses potential failure modes like overturning, sliding, compression, and tension. For earth dams, it outlines the components including shells and cores, and failure causes such as hydraulic failure from overtopping, seepage failure, and structural failure from cracking or sliding. It provides details on preliminary sections for earth dams and criteria for their safe design.
1. Dams are constructed across rivers to store flowing water for uses like hydropower, irrigation, water supply, flood control, and navigation.
2. The key forces acting on a gravity dam include its self-weight, which provides stability, and water pressure from the reservoir, which acts to overturn the dam. Uplift, earthquake loads, silt pressure, and ice pressure are other important forces that must be estimated based on assumptions and available data.
3. The weight of the dam per unit length is calculated based on the cross-sectional area and unit weight of the concrete or masonry used. The total weight acts at the centroid of the cross-section and is the main stabil
Role of Engineering Geology In Resevoirs,Dams & Tunneling.kaustubhpetare
The document discusses the role of engineering geology in reservoirs, dams, and tunneling. It provides information on how geological factors must be considered when selecting dam and reservoir sites. The types of dams are described, including gravity, buttress, arch, and embankment dams. Key geological considerations for dam foundations include the strength and stability of the underlying rocks. Bedding planes dipping upstream are most suitable, while faults and folds can increase risks. Thorough geological surveys and site investigations are needed before construction to evaluate the foundation conditions.
The document discusses various geological considerations for selecting dam sites, including:
1) Topography and competent rock formations are essential, with narrow valleys and rocks like granite or basalt preferred.
2) Geological structures like faults, joints, or unfavorable dips must be absent.
3) Factors like weathering, intrusions, fracturing, and alternating soft/hard beds can impact stability and require treatment.
4) Undisturbed horizontal strata or gently dipping strata upstream are most suitable, while downstream dips or complex folding can cause issues. Proper site selection and treatment are crucial to a dam's safety and cost-effectiveness.
The document discusses dams, including their purposes, types, and factors to consider for site selection and investigation. It provides information on different types of dams including earth, rock, concrete, gravity, arch, buttress, and composite dams. Key factors for dam site selection and investigation include geological conditions, hydrology, availability of construction materials, and environmental impacts. Detailed geological investigations are necessary to evaluate the foundation stability, water tightness of the reservoir, and availability of local construction materials.
The document discusses dams, including their purposes, types, and factors considered in site selection and design. It provides information on different types of dams such as earth, rock, concrete, gravity, arch, buttress, and composite dams. Key factors for dam site investigation are described, including geological conditions, hydrology, material availability, and how the type of dam is selected based on these factors.
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
Abstract: Geo-technical engineering as a subject has developed considerably in the past four decades. There
has been remarkable development in the fields of design, research and construction of dam. India is capable of
designing and constructing a dam that would withstand a seismic jolt. The country needs water and electricity
to provide its people good living standards. Hydropower is the solution to the country's requirements, and this
can be achieved by storing water in dams.
In the past, earthquake effects may have been treated too lightly in dam design. Are such dams safe,
and how have they fared in previous earthquakes, this Paper will be limited to the some of finding about one
concrete types.
What will happen to dams during severe earthquake shaking? It is obvious that at present engineers
cannot answer this question with any certainty. But we are very much aware of the threat of disastrous losses of
life and damage to property if dams should fail, and we are making great effort to increase our under standing
of this complex topic.
This Paper deals with the case study of totaladoh Dam Situated in Vidarbha Region of Maharashtra
for Seismic Analysis by I.S.Code method (Simple Beam Analysis method). This also includes future scope of
analyzing the same dam for Seismic safety by very accurate method i.e. finite element method.
Keywords: Earthquake, The finite element method, Indian Standard codes(I.S.Code), horizontal
seismic coefficient (αh ),Hydrostatic pressure, Seismic analysis,
This document provides information on dams and reservoirs. It begins with definitions of dams and discusses the structure of dams. The main types of dams are then described - gravity dams, arch dams, buttress dams, embankment dams. Examples are given of major dams like the Three Gorges Dam and Hoover Dam. Dams in Thailand are also discussed. The document outlines the advantages and disadvantages of dams. It provides classifications of dams and factors to consider for different dam types. Forces acting on gravity and arch dams are explained.
This document discusses important geological considerations for constructing dams. Location, permeability of surrounding rock, and stability are some key factors. Different dam types suit different geological conditions - for example, gravity dams require hard rock foundations while rockfill dams can be built where foundations are less stable. Curtain grouting can restrict seepage in permeable rock. Engineering geology aims to evaluate factors like seismic activity, landslides, and environmental impacts when planning dam projects.
This document discusses important geological considerations for constructing dams. Location, permeability of surrounding rock, and stability are some key factors. Different dam types suit different geological conditions - for example, gravity dams require hard rock foundations while rockfill dams can be built where foundations are less stable. Curtain grouting can restrict seepage in permeable rock. Engineering geology aims to evaluate factors like seismic activity, landslides, and environmental impacts when planning dam projects.
This document discusses different types of hydraulic structures used for water storage. It describes storage dams, which are structures built across rivers to store water for future use. The key components of storage dams are the dam structure itself to obstruct river flow, a spillway to discharge excess flood water, and outlets to withdraw stored water. Embankment dams, made of earth and/or rock fill, and concrete dams are the main types discussed. Embankment dams are more common due to technical and economic reasons. Earth-fill, rock-fill, gravity, buttress, and arch dams are further described as varieties of embankment and concrete dams.
This document provides information on drainage and inspection galleries in dams. The key points are:
1. Drainage and inspection galleries are tunnels within dams used for inspection, drainage, and access to outlet gates and spillway gates. Large dams have multiple galleries at different levels.
2. Drainage galleries reduce uplift forces in the dam foundation and body. They also facilitate inspection of the dam body.
3. Drainage galleries are typically placed at 7.5% of the dam height and have a minimum distance of 3 meters from the upstream face and foundation. They are usually 1.5 meters wide and 2.5 meters high with reinforcement. Drainage holes release uplift forces in the foundation and body.
This document discusses dams and reservoirs. It begins with definitions of dams and describes their basic structure. It then discusses the advantages and disadvantages of dams, and provides examples of different types of dams including gravity dams, arch dams, buttress dams, and embankment dams. The document concludes with information on dam failures and statistics on types of dams.
Construction Of A Viaduct/Bridge: An OverviewSourav Goswami
This document is a submission by Sourav Goswami describing his 7-day internship project focused on the construction of a metro rail bridge. The project was conducted under Rail Vikas Nigam Limited and Gammon India Limited. Sourav thanks the project guides and staff who provided guidance and knowledge about bridge construction activities including piling, pile caps, piers, bearings and segments.
Bridges: Classification of bridges – with respect to construction
materials, structural behavior of super structure, span, sub structure,
purpose. Temporary and movable bridges. Factors affecting site
selection. Various loads/stresses acting on bridges. Bridge hydrology –
design discharge, water way, afflux, scour depth, economical span.
Bridge components – foundation, piers, abutments, wing wall, approach,
bearings, floor, girders, cables, suspenders. Methods of erection of
different types of bridges. River training works and maintenance of
bridges. Testing and strengthening of bridges. Bridge architect.
This document discusses important geological considerations for dam site selection, including:
1) Narrow river valleys and shallow bedrock are preferable as they reduce construction costs.
2) Bedrock foundations must be competent to safely support the dam. Igneous rocks are generally most suitable.
3) Geological structures like horizontal or mildly tilted strata are ideal, while steep dips, faults, folds or intense fracturing indicate less competent foundations.
The Rion-Antirion Bridge in Greece connects the Peloponnese peninsula to the western mainland via a 2252m long cable-stayed main bridge that spans the Corinth Strait. It was designed to withstand the severe seismic activity and possible fault movements in the area. The main bridge uses four pylons supported by large reinforced soil foundations to distribute seismic forces to the deep weak soil layers. Dynamic analysis showed that during major earthquakes, the reinforced soil and pylon foundations would yield and slide as designed to dissipate energy without compromising the structure. The continuous suspended deck acts as a flexible element that can accommodate displacements without damage. The bridge's innovative design allows all components to work together to resist earthquake forces through
The document discusses three main failure modes for gravity dams: sliding failures, overturning failures, and structural failures. Sliding failures occur when horizontal forces exceed the frictional resistance between the dam and foundation, causing the dam to slide. Overturning failures happen when horizontal and vertical forces create overturning moments that exceed the dam's weight, potentially causing the dam to rotate or overturn. Structural failures result from tensile or compressive stresses exceeding the strength of the dam's materials, which can cause cracking and eventual failure. Proper design and construction aim to balance forces and stresses to maintain stability and prevent these failure modes.
Canal lining is the process of reducing seepage loss of irrigation water by adding an impermeable layer to the edges of the trench. Seepage can result in losses of 30 to 50 percent of irrigation water from canals, so adding lining can make irrigation systems more efficient. Canal linings are also used to prevent weed growth, which can spread throughout an irrigation system and reduce water flow. Lining a canal can also prevent waterlogging around low-lying areas of the canal. By making a canal less permeable, the water velocity increases resulting in a greater overall discharge. Increased velocity also reduces the amount of evaporation and silting that occurs, making the canal more efficient.
Static and Dynamic Analysis of Multi - storied Building in Seismic Zones.pdfVenkataraju Badanapuri
Generally, the building is subjected to seismic loads the infill masonry wall is considered as nonstructural elements and their stiffness contribution are ignored during the analysis. RC frame building with open ground story is called as soft story, similarly soft story effect can be observed when soft story at different level of the structure is constructed. In recent earthquake it is observed that a building with discontinuous in stiffness and mass subjected to concentration of forces and the point of discontinuity which may leads to failure of members at the junction and collapse of building.
More Related Content
Similar to Seismic Forces and Stability Analysis of Gravity Dam.pdf
This document discusses factors to consider for dam site selection and investigation. The key factors include:
1. Geological conditions of the proposed site, including rock type, structure, strength, porosity, and permeability, which can impact dam stability and water tightness.
2. Hydrological factors like stream flow, rainfall, and reservoir characteristics, which determine water availability and storage.
3. Access and availability of construction materials. Suitable rock or earth is needed for building the dam.
4. Environmental impacts must also be considered, such as effects on ecology, water quality, and local communities. A thorough investigation of all relevant geological, hydrological and environmental factors is needed to select the optimal dam site.
This document discusses gravity dams and earth dams. For gravity dams, it describes the typical cross-section and forces acting on the dam, including water pressure, dam weight, uplift pressure, and more. It also discusses potential failure modes like overturning, sliding, compression, and tension. For earth dams, it outlines the components including shells and cores, and failure causes such as hydraulic failure from overtopping, seepage failure, and structural failure from cracking or sliding. It provides details on preliminary sections for earth dams and criteria for their safe design.
1. Dams are constructed across rivers to store flowing water for uses like hydropower, irrigation, water supply, flood control, and navigation.
2. The key forces acting on a gravity dam include its self-weight, which provides stability, and water pressure from the reservoir, which acts to overturn the dam. Uplift, earthquake loads, silt pressure, and ice pressure are other important forces that must be estimated based on assumptions and available data.
3. The weight of the dam per unit length is calculated based on the cross-sectional area and unit weight of the concrete or masonry used. The total weight acts at the centroid of the cross-section and is the main stabil
Role of Engineering Geology In Resevoirs,Dams & Tunneling.kaustubhpetare
The document discusses the role of engineering geology in reservoirs, dams, and tunneling. It provides information on how geological factors must be considered when selecting dam and reservoir sites. The types of dams are described, including gravity, buttress, arch, and embankment dams. Key geological considerations for dam foundations include the strength and stability of the underlying rocks. Bedding planes dipping upstream are most suitable, while faults and folds can increase risks. Thorough geological surveys and site investigations are needed before construction to evaluate the foundation conditions.
The document discusses various geological considerations for selecting dam sites, including:
1) Topography and competent rock formations are essential, with narrow valleys and rocks like granite or basalt preferred.
2) Geological structures like faults, joints, or unfavorable dips must be absent.
3) Factors like weathering, intrusions, fracturing, and alternating soft/hard beds can impact stability and require treatment.
4) Undisturbed horizontal strata or gently dipping strata upstream are most suitable, while downstream dips or complex folding can cause issues. Proper site selection and treatment are crucial to a dam's safety and cost-effectiveness.
The document discusses dams, including their purposes, types, and factors to consider for site selection and investigation. It provides information on different types of dams including earth, rock, concrete, gravity, arch, buttress, and composite dams. Key factors for dam site selection and investigation include geological conditions, hydrology, availability of construction materials, and environmental impacts. Detailed geological investigations are necessary to evaluate the foundation stability, water tightness of the reservoir, and availability of local construction materials.
The document discusses dams, including their purposes, types, and factors considered in site selection and design. It provides information on different types of dams such as earth, rock, concrete, gravity, arch, buttress, and composite dams. Key factors for dam site investigation are described, including geological conditions, hydrology, material availability, and how the type of dam is selected based on these factors.
The International Journal of Engineering & Science is aimed at providing a platform for researchers, engineers, scientists, or educators to publish their original research results, to exchange new ideas, to disseminate information in innovative designs, engineering experiences and technological skills. It is also the Journal's objective to promote engineering and technology education. All papers submitted to the Journal will be blind peer-reviewed. Only original articles will be published.
Abstract: Geo-technical engineering as a subject has developed considerably in the past four decades. There
has been remarkable development in the fields of design, research and construction of dam. India is capable of
designing and constructing a dam that would withstand a seismic jolt. The country needs water and electricity
to provide its people good living standards. Hydropower is the solution to the country's requirements, and this
can be achieved by storing water in dams.
In the past, earthquake effects may have been treated too lightly in dam design. Are such dams safe,
and how have they fared in previous earthquakes, this Paper will be limited to the some of finding about one
concrete types.
What will happen to dams during severe earthquake shaking? It is obvious that at present engineers
cannot answer this question with any certainty. But we are very much aware of the threat of disastrous losses of
life and damage to property if dams should fail, and we are making great effort to increase our under standing
of this complex topic.
This Paper deals with the case study of totaladoh Dam Situated in Vidarbha Region of Maharashtra
for Seismic Analysis by I.S.Code method (Simple Beam Analysis method). This also includes future scope of
analyzing the same dam for Seismic safety by very accurate method i.e. finite element method.
Keywords: Earthquake, The finite element method, Indian Standard codes(I.S.Code), horizontal
seismic coefficient (αh ),Hydrostatic pressure, Seismic analysis,
This document provides information on dams and reservoirs. It begins with definitions of dams and discusses the structure of dams. The main types of dams are then described - gravity dams, arch dams, buttress dams, embankment dams. Examples are given of major dams like the Three Gorges Dam and Hoover Dam. Dams in Thailand are also discussed. The document outlines the advantages and disadvantages of dams. It provides classifications of dams and factors to consider for different dam types. Forces acting on gravity and arch dams are explained.
This document discusses important geological considerations for constructing dams. Location, permeability of surrounding rock, and stability are some key factors. Different dam types suit different geological conditions - for example, gravity dams require hard rock foundations while rockfill dams can be built where foundations are less stable. Curtain grouting can restrict seepage in permeable rock. Engineering geology aims to evaluate factors like seismic activity, landslides, and environmental impacts when planning dam projects.
This document discusses important geological considerations for constructing dams. Location, permeability of surrounding rock, and stability are some key factors. Different dam types suit different geological conditions - for example, gravity dams require hard rock foundations while rockfill dams can be built where foundations are less stable. Curtain grouting can restrict seepage in permeable rock. Engineering geology aims to evaluate factors like seismic activity, landslides, and environmental impacts when planning dam projects.
This document discusses different types of hydraulic structures used for water storage. It describes storage dams, which are structures built across rivers to store water for future use. The key components of storage dams are the dam structure itself to obstruct river flow, a spillway to discharge excess flood water, and outlets to withdraw stored water. Embankment dams, made of earth and/or rock fill, and concrete dams are the main types discussed. Embankment dams are more common due to technical and economic reasons. Earth-fill, rock-fill, gravity, buttress, and arch dams are further described as varieties of embankment and concrete dams.
This document provides information on drainage and inspection galleries in dams. The key points are:
1. Drainage and inspection galleries are tunnels within dams used for inspection, drainage, and access to outlet gates and spillway gates. Large dams have multiple galleries at different levels.
2. Drainage galleries reduce uplift forces in the dam foundation and body. They also facilitate inspection of the dam body.
3. Drainage galleries are typically placed at 7.5% of the dam height and have a minimum distance of 3 meters from the upstream face and foundation. They are usually 1.5 meters wide and 2.5 meters high with reinforcement. Drainage holes release uplift forces in the foundation and body.
This document discusses dams and reservoirs. It begins with definitions of dams and describes their basic structure. It then discusses the advantages and disadvantages of dams, and provides examples of different types of dams including gravity dams, arch dams, buttress dams, and embankment dams. The document concludes with information on dam failures and statistics on types of dams.
Construction Of A Viaduct/Bridge: An OverviewSourav Goswami
This document is a submission by Sourav Goswami describing his 7-day internship project focused on the construction of a metro rail bridge. The project was conducted under Rail Vikas Nigam Limited and Gammon India Limited. Sourav thanks the project guides and staff who provided guidance and knowledge about bridge construction activities including piling, pile caps, piers, bearings and segments.
Bridges: Classification of bridges – with respect to construction
materials, structural behavior of super structure, span, sub structure,
purpose. Temporary and movable bridges. Factors affecting site
selection. Various loads/stresses acting on bridges. Bridge hydrology –
design discharge, water way, afflux, scour depth, economical span.
Bridge components – foundation, piers, abutments, wing wall, approach,
bearings, floor, girders, cables, suspenders. Methods of erection of
different types of bridges. River training works and maintenance of
bridges. Testing and strengthening of bridges. Bridge architect.
This document discusses important geological considerations for dam site selection, including:
1) Narrow river valleys and shallow bedrock are preferable as they reduce construction costs.
2) Bedrock foundations must be competent to safely support the dam. Igneous rocks are generally most suitable.
3) Geological structures like horizontal or mildly tilted strata are ideal, while steep dips, faults, folds or intense fracturing indicate less competent foundations.
The Rion-Antirion Bridge in Greece connects the Peloponnese peninsula to the western mainland via a 2252m long cable-stayed main bridge that spans the Corinth Strait. It was designed to withstand the severe seismic activity and possible fault movements in the area. The main bridge uses four pylons supported by large reinforced soil foundations to distribute seismic forces to the deep weak soil layers. Dynamic analysis showed that during major earthquakes, the reinforced soil and pylon foundations would yield and slide as designed to dissipate energy without compromising the structure. The continuous suspended deck acts as a flexible element that can accommodate displacements without damage. The bridge's innovative design allows all components to work together to resist earthquake forces through
The document discusses three main failure modes for gravity dams: sliding failures, overturning failures, and structural failures. Sliding failures occur when horizontal forces exceed the frictional resistance between the dam and foundation, causing the dam to slide. Overturning failures happen when horizontal and vertical forces create overturning moments that exceed the dam's weight, potentially causing the dam to rotate or overturn. Structural failures result from tensile or compressive stresses exceeding the strength of the dam's materials, which can cause cracking and eventual failure. Proper design and construction aim to balance forces and stresses to maintain stability and prevent these failure modes.
Similar to Seismic Forces and Stability Analysis of Gravity Dam.pdf (20)
Canal lining is the process of reducing seepage loss of irrigation water by adding an impermeable layer to the edges of the trench. Seepage can result in losses of 30 to 50 percent of irrigation water from canals, so adding lining can make irrigation systems more efficient. Canal linings are also used to prevent weed growth, which can spread throughout an irrigation system and reduce water flow. Lining a canal can also prevent waterlogging around low-lying areas of the canal. By making a canal less permeable, the water velocity increases resulting in a greater overall discharge. Increased velocity also reduces the amount of evaporation and silting that occurs, making the canal more efficient.
Static and Dynamic Analysis of Multi - storied Building in Seismic Zones.pdfVenkataraju Badanapuri
Generally, the building is subjected to seismic loads the infill masonry wall is considered as nonstructural elements and their stiffness contribution are ignored during the analysis. RC frame building with open ground story is called as soft story, similarly soft story effect can be observed when soft story at different level of the structure is constructed. In recent earthquake it is observed that a building with discontinuous in stiffness and mass subjected to concentration of forces and the point of discontinuity which may leads to failure of members at the junction and collapse of building.
Study on Stress-Strain behaviour of M50 Grade High Strength Glass Fibre Reinf...Venkataraju Badanapuri
Self-compacting concrete (SCC) can be defined as a fresh concrete which possesses superior flowability under maintained stability
(i.e., no segregation) thus allowing self-compaction—that is, material consolidation without addition of energy. It was first developed in Japan
in 1988 in order to achieve durable concrete structures by improving quality in the construction process. This was also partly in response to the
reduction in the numbers of skilled workers available in the industry. This paper outlines a brief history of SCC from its origins in Japan to the
development of the material throughout Europe. Research and development into SCC in the UK and Europe are discussed, together with a look
at the future for the material in Europe and the rest of the world
Analysis and Design of Elevated Intez Water Tank based on Normal Frame Stagin...Venkataraju Badanapuri
Water is as important commodity as food and air for the existence of life. All plants and animals must have water to survive. If
there was no water there would be no life on earth. As water is very precious and due to the scarcity of drinking water in day-to-day life one
has to take care of every drop. Anelevated Intez water tank is used to store water for fire protection and potable drinking water within a
designated area or community over the daily requirement. Elevated Intez tanks allow the natural force of gravity to produce consistent water
pressure throughout the system. Elevated Intez water tanks are one of the most important structures in earthquake high regions. In major
cities and also in rural areas elevated or overhead water tanks forms an integral part of water supply scheme.
Design Principles that are involved in the Design of Flow over an Ogee Crest ...Venkataraju Badanapuri
The ogee-crested spillway’s ability to pass flows efficiently and safely, when properly designed and constructed, with
relatively good flow measuring capabilities, has enabled engineers to use it in a wide variety of situations as a water discharge structure
(USACE, 1988; USBR, 1973). The ogee-crested spillway’s performance attributes are due to its shape being derived from the lower surface of an aerated nappe flowing over a sharp-crested weir.
Water Resources Scenario in India Its Requirement, Water Degradation and Poll...Venkataraju Badanapuri
Earth's water resources, including rivers, lakes,
oceans, and underground aquifers, are under stress in
many regions. Humans need water for drinking,
sanitation, agriculture, and industry; and
contaminated water can spread illnesses and disease
vectors, so clean water is both an environmental and a
public health issue. In this article, learn how water is
distributed around the globe; how it cycles among the
oceans, atmosphere, and land; and how human
activities are affecting our finite supply of usable water.
INDIAN SCENARIO OF WATER RESOURCES - AN OVERVIEW, INTEGRATED WATER MANAGEMENT...Venkataraju Badanapuri
Water is life sustaining liquid. It is one of the most important natural resources which is essential for the existence of living organisms and things including humans and wildlife, food production, food security, sustainable development and alleviate the poverty of the country. Despite of having blessed with enormous water resources (e.g., Mt. Himalaya’s originated Holy River Ganges, and its several tributaries from the north, Kaveri River in the south, ever rain forests [e.g., Mousinram near Cherrapunji], world’s tastiest waters of the Siruvani River in Coimbatore, Western Ghats Basin, network of fresh water resources etc.,), “water problem” is huge ‘a big threat and cross cut problem in India’. Water is most essential and widely distributed key resource to meet the basic need for livelihoods,
AN OVERVIEW OF INTEGRATED THEORY OF IRRIGATION EFFICIENCY AND UNIFORMITY AND ...Venkataraju Badanapuri
The irrigation efficiency, crop water use efficiency, and irrigation uniformity evaluation terms that are relevant to irrigation systems and management practices currently used in India, and around the world. The definitions and equations described can be used by crop consultants, irrigation district personnel, and university, state, and private agency personnel to evaluate how efficiently irrigation water is applied and/or used by the crop, and can help to promote better or improved use of water resources in agriculture. As available water resources become scarcer, more emphasis is given to efficient use of irrigation water for maximum economic return and water resources sustainability.
Following are some suggestions for future research. As GFRSCC technology is now being adopted in many countries throughout the world, in the absence of suitable
standardized test methods it is necessary to examine the existing test methods and identify or, when necessary, develop test methods suitable for acceptance as International Standards. Such test methods have to be capable of a rapid and reliable assessment of key
properties of fresh SCC on a construction site. At the same time, the testing equipment should be reliable, easily portable and inexpensive. The test procedure should be carried out by a single operator and the test results have to be interpreted with a minimum of training. Also, the results have to define and specify different GFRSCC mixes. One primary application of these test methods would be in verification of compliance on sites and in concrete production plants, if self- compacting concrete could be manufactured in large quantities..
Following are some suggestions for future research. As GFRSCC technology is now being adopted in many ountries throughout the world, in the absence of suitable standardized test methods it is necessary to examine the existing test methods and identify or, when necessary, develop test methods suitable for acceptance as international Standards. Such test methods have to be capable of a rapid and reliable assessment of key
properties of fresh SCC on a construction site. At the same time, the testing equipment should be reliable, easily portable and inexpensive. The test procedure should be carried
out by a single operator and the test results have to be interpreted with a minimum of
training. Also, the results have to define and specify different GFRSCC mixes. One
primary application of these test methods would be in verification of compliance on sites
and in concrete production plants, if self- compacting concrete could be manufactured in
large quantities..
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
Harnessing WebAssembly for Real-time Stateless Streaming PipelinesChristina Lin
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.
We have compiled the most important slides from each speaker's presentation. This year’s compilation, available for free, captures the key insights and contributions shared during the DfMAy 2024 conference.
Literature Review Basics and Understanding Reference Management.pptxDr Ramhari Poudyal
Three-day training on academic research focuses on analytical tools at United Technical College, supported by the University Grant Commission, Nepal. 24-26 May 2024
International Conference on NLP, Artificial Intelligence, Machine Learning an...gerogepatton
International Conference on NLP, Artificial Intelligence, Machine Learning and Applications (NLAIM 2024) offers a premier global platform for exchanging insights and findings in the theory, methodology, and applications of NLP, Artificial Intelligence, Machine Learning, and their applications. The conference seeks substantial contributions across all key domains of NLP, Artificial Intelligence, Machine Learning, and their practical applications, aiming to foster both theoretical advancements and real-world implementations. With a focus on facilitating collaboration between researchers and practitioners from academia and industry, the conference serves as a nexus for sharing the latest developments in the field.
DEEP LEARNING FOR SMART GRID INTRUSION DETECTION: A HYBRID CNN-LSTM-BASED MODELgerogepatton
As digital technology becomes more deeply embedded in power systems, protecting the communication
networks of Smart Grids (SG) has emerged as a critical concern. Distributed Network Protocol 3 (DNP3)
represents a multi-tiered application layer protocol extensively utilized in Supervisory Control and Data
Acquisition (SCADA)-based smart grids to facilitate real-time data gathering and control functionalities.
Robust Intrusion Detection Systems (IDS) are necessary for early threat detection and mitigation because
of the interconnection of these networks, which makes them vulnerable to a variety of cyberattacks. To
solve this issue, this paper develops a hybrid Deep Learning (DL) model specifically designed for intrusion
detection in smart grids. The proposed approach is a combination of the Convolutional Neural Network
(CNN) and the Long-Short-Term Memory algorithms (LSTM). We employed a recent intrusion detection
dataset (DNP3), which focuses on unauthorized commands and Denial of Service (DoS) cyberattacks, to
train and test our model. The results of our experiments show that our CNN-LSTM method is much better
at finding smart grid intrusions than other deep learning algorithms used for classification. In addition,
our proposed approach improves accuracy, precision, recall, and F1 score, achieving a high detection
accuracy rate of 99.50%.
6th International Conference on Machine Learning & Applications (CMLA 2024)ClaraZara1
6th International Conference on Machine Learning & Applications (CMLA 2024) will provide an excellent international forum for sharing knowledge and results in theory, methodology and applications of on Machine Learning & Applications.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
A review on techniques and modelling methodologies used for checking electrom...nooriasukmaningtyas
The proper function of the integrated circuit (IC) in an inhibiting electromagnetic environment has always been a serious concern throughout the decades of revolution in the world of electronics, from disjunct devices to today’s integrated circuit technology, where billions of transistors are combined on a single chip. The automotive industry and smart vehicles in particular, are confronting design issues such as being prone to electromagnetic interference (EMI). Electronic control devices calculate incorrect outputs because of EMI and sensors give misleading values which can prove fatal in case of automotives. In this paper, the authors have non exhaustively tried to review research work concerned with the investigation of EMI in ICs and prediction of this EMI using various modelling methodologies and measurement setups.
A review on techniques and modelling methodologies used for checking electrom...
Seismic Forces and Stability Analysis of Gravity Dam.pdf
1. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
Seismic Forces and Stability Analysis of Gravity
Dam
Venkata Raju Badanapuri
Executive Engineer, Water Resources Department, Government of Andhra Pradesh, India
Abstract: A gravity dam is a solid structure, made of concrete or masonry, constructed across a river to create a reservoir on its
upstream. The section of the gravity dam is approximately triangular in shape, with its apex at its top and maximum width at bottom.
The section is so proportioned that it resists the various forces acting on it by its own weight. Most of the gravity dams are solid, so that
no bending stress is introduced at any point and hence, they are sometimes known as solid gravity dams to distinguish them from hollow
gravity dams in those hollow spaces are kept to reduce the weight. Early gravity dams were built of masonry, but now-a-days with
improved methods of construction, quality control and curing, concrete is most commonly used for the construction of modern gravity
dams. A gravity dam is generally straight in plan and, therefore, it is also called straight gravity dam. However, in some cases, it may be
slightly curved in plan, with its convexity upstream. When the curvature becomes significant, it becomes on arch dam. The gravity dams
are usually provided with an overflow spillway in some portion of its length. The dam thus consists of two sections; namely, the non-
overflow section and the overflow section or spillway section. The design of these two sections is done separately because the loading
conditions are different. The overflow section is usually provided with spillway gates. The ratio of the base width to height of most of the
gravity dam is less than 1.0. The upstream face is vertical or slightly inclined. The slope of the downstream face usually varies between
0.7: 1 to 0.8: 1. Gravity dams are particularly suited across gorges with very steep side slopes where earth dams might slip. Where good
foundations are available, gravity dams can be built upto any height. Gravity dams are also usually cheaper than earth dams if suitable
soils are not available for the construction of earth dams. This type of dam is the most permanent one, and requires little maintenance.
The most ancient gravity, dam on record was built in Egypt more than 400 years B.C. of uncemented masonry. Archaeological experts
believe that this dam was kept in perfect condition for more than 45 centuries. The highest gravity dam in the world is Grand Dixence
Dam in Switzerland, which is 285 m high. The second highest gravity dam is Bhakra Dam in India, which has a height of 226 m. The
aim of the study is to analyse the dam for stability and seismic forces. Dam being one of the mega structures it becomes prime important
to design and analyse such structure with keen observation considering various factors affecting them. As it is one of the lifesaving
structures, it is again important to analyse such structure for major forces like earthquake. Keeping this in mind, in this paper the study
is done for finding out the result that makes dam stable against forces acting on it with and without considering seismic forces. The
study is done considering the hypnotically dam subjected to pre decided geographical factors like type of soil, its density, seismic zone
etc. further this experimental work is done for dam full (with and without considering uplift pressure) and empty condition. This
designing is done following IS code criteria. Further in paper work various such gravity dams subjected to different factors are
analysed. The results of analysis are tabulated over here and the various forces responsible for failure of dam are highlighted in
conclusion.
Keywords: Gravity Dam, Seismic Forces, Sliding, Stability, Analysis
1. Introduction
A concrete dam must be able to safely withstand the static
forces that tend to cause sliding or overturning, as well as
the additional dynamic forces induced by the ground
motions of the design earthquake. If you are an owner or
otherwise have responsibility for a concrete dam, you should
know whether that dam is stable under all potential loading
conditions. To verify a dam's stability, investigations and
analyses may be necessary. This paper provides background
information about types of concrete dams and the
significance of static and seismic stability of concrete dams.
It also describes modes of static and seismic stability
failure.A concrete dam is a dam constructed mainly of cast-
in-place or roller-compacted concrete. There are three major
types of concrete dams, 1. gravity dams, 2. arch dams, and 3.
buttress dams.
1) A gravity dam is a massive concrete structure, roughly
triangular in shape, and designed so that its weight
ensures structural stability against the hydrostatic
pressure of the impounded water and other forces that
may act on the dam. Gravity dams may be classified by
plan as straight gravity dams and curved gravity dams,
depending upon the axis alignment.
2) An arch dam is a solid concrete structure, usually thinner
than a gravity dam, that is arched upstream. An arch dam
obtains most of its stability by transmitting the reservoir
load into the canyon walls by arch action.
3) A buttress dam, a form of gravity dam, is comprised of
two or three basic structural elements: a watertight
upstream face, buttresses that support the face and
transfer the load from the face to the foundation, and
sometimes a concrete apron. Buttress dams depend on
their own weight and the weight of the water acting on
the upstream face to maintain stability.
Another type of dam that may require evaluation is the
masonry dam. A masonry dam is constructed mainly of
stone, brick, rock, or concrete blocks joined with mortar.
Most masonry dams are older gravity dams, although a few
are arch dams. Each type of dam may fail due to static or
seismic instability, and an evaluation should be made of a
particular dam's susceptibility to such instability.
2. Historical Perspective
Concrete (or masonry) dams have some inherent advantages
over embankment dams. They require less, albeit more
expensive, construction material, and they are resistant to
Paper ID: ART20199058 10.21275/ART20199058 2021
2. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
overtopping and to internal erosion by seepage. On the other
hand, they generally require more competent foundations
and abutments because of their rigidity. Historically concrete
dams are relatively safe when compared to their earth fill
and rockfill counterparts. This is because of their inherent
durability and high resistance to erosion. Seepage and
overtopping situations that would cause failure in an earth
fill or rockfill dam would not, in most cases, cause a
concrete dam to fail. Nevertheless, there still have been
significant failures of all types of concrete dams continuing
into recent times. Most failures can be traced to overstress of
foundations or abutments because the in-situ materials were
not adequate to sustain the applied loads or deteriorated as
seepage developed. Deterioration of concrete and
particularly of the mortar in older masonry structures has
also resulted in several failures.
3. Gravity Dam Basic Definitions
Terminology relating to the design and analysis of gravity
dams and definitions of the parts of gravity dams as used in
this paper are as follows:
A plan is an orthographic projection on a horizontal plane,
showing the main features ofa dam and its appurtenant
works with respect to the topography and available
geological data. A plan should be oriented so that the
direction of stream flow is toward the top or toward the right
of the drawing. A profile is a developed elevation of the
intersection of a dam with the original ground surface, rock
surface, or excavation surface along the axis of the dam, the
upstream face, the downstream face, or other designated
location. The axis of the dam is a vertical reference plane
usually defined by the upstream edge of the top of the dam.
A section is a representation of a dam as it is taken
horizontally through the dam. A cantilever section is a
vertical section taken normal to the axis and usually oriented
with the reservoir to the left. A beam element, or beam, is a
portion of a gravity dam bounded by two horizontal planes
0.3m apart. For purposes of analysis the edges of the
elements are assumed to be vertical. A cantilever element, or
cantilever, is a portion of a gravity dam bounded by two
vertical planes normal to the axis and 0.3 m apart, A twisted
structure consists of vertical elements with the same
structural properties as the cantilevers, and of horizontal
elements with the same properties as the beams. The twisted
structure resists torsion in both the vertical and horizontal
planes. The height of a cantilever is the vertical distance
between the base elevation of the cantilever section and the
top of the dam. The thickness of a dam at any point is the
distance between upstream and downstream faces along a
line normal to the axis through the point. The abutment of a
beam element is the surface, at either end of the beam,
which contacts the rock of the canyon wall. The crest of a
dam is the top of the dam.
1) Axis of the dam: The axis of the gravity dam is the line
of the upstream edge of the top (or crown) of the dam. If
the upstream face of the dam is vertical, the axis of the
dam coincides with the plan of the upstream edge. In
plan, the axis of the dam indicates the horizontal trace of
the upstream edge of the top of the dam. The axis of the
dam in plan is also called the baseline of the dam. The
axis of the dam in plan is usually straight. However, in
some special cases, it may be slightly curved upstream,
or it may consist of a combination of slightly
2) Curved RIGHT portions at ends and a central
ABUTMENT straight portion to take the best advantages
of the topography of the site.
3) Length of the dam: The length of the dam is the distance
from one abutment to the other, measured along the axis
of the dam at the level of the top of the dam. It is the
usual practice to mark the distance from the left abutment
to the right abutment. The left abutment is one which is
to the left of the person moving along with the current of
water.
4) Structural height of the dam: The structural height of the
dam is the difference in elevations of the top of the dam
and the lowest point in the excavated foundation. It,
however, does not include the depth of special geological
features of foundations such as narrow fault zones below
the foundation. In general, the height of the dam means
its structural height.
5) Maximum base width of the dam: The maximum base
width of the dam is the maximum horizontal distance
between the heel and the toe of the maximum section of
thedam in the middle of the valley.
6) Toe and Heel: The toe of the dam isthe downstream edge
of the base, and the heel is the upstream edge of thebase.
When a person moves along with water current, his toe
comes first and heel comes later.
7) Hydraulic height of the dam: The hydraulic height of the
dam is equal to the difference in elevations of the highest
controlled water surface on the upstream of the dam (i. e.
FRL) and the lowest point in the river bed.
4. Static and seismic stability
Concrete dams are subject to various loads, including
external and internal water pressures, earth pressures due to
siltation, ice pressures, and earthquake forces. Stability
analyses are performed to ensure that the dam and its
foundation are capable of safely accommodating these loads.
Two major classifications of stability are discussed in this
paper static stability and seismic stability.
Static Stability
Ability of a dam to resist the static forces that tend to induce
sliding or overturning.
Seismic Stability: Ability of a dam to resist the additional
dynamic forces induced by the ground motions of an
earthquake.
5. Scope
A concrete gravity dam, as discussed in this paper, is a solid
concrete structure so designed and shaped that its weight is
sufficient to ensure stability against the effects of all
imposed forces. Other types of dams exist which also
maintain their stability through the principle of gravity, such
as buttress and hollow gravity dams, but these are outside
the scope of this paper. Further, discussions in this paper are
limited to damson rock foundations and do not include
smaller
Paper ID: ART20199058 10.21275/ART20199058 2022
3. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
dams generally less than 15 m high which are discussed in
the Bureau of Reclamation publication “Design of Small
Dams”.
The complete design of a concrete gravity dam includes not
only the determination of the most efficient and economical
proportions for the water impounding structure, but also the
determination of the most suitable appurtenant structures for
the control and release of the impounded water consistent
with the purpose or function of the project. This paper
presents the basic assumptions, design considerations,
methods of analysis, and procedures used by designers
within the Engineering and Research Centre, Bureau of
Reclamation, for the design of a gravity damand its
appurtenances.
6. Classifications
Gravity dams may be classified by plan as straight gravity
dams and curved gravity dams, depending upon the axis
alignment. The principal difference in these two classes is in
the method of analysis. Whereas a straight gravity dam
would be analysed by one of the gravity methods discussed
in this paper, a curved gravity dam would be analysed as an
arch dam structure. For statistical purposes, gravity dams are
classified with reference to their structural height. Dams up
to30 m high are generally considered as low dams, dams
from 30 m to 90 m high as medium-height dams, and dams
over 90 m high as high dams.
7. Design Philosophy
The Bureau of Reclamation’s philosophy of concrete dam
design is founded on rational and consistent criteria which
provide for safe, economical, functional, durable, and easily
maintained structures. It is desirable, therefore, to establish,
maintain, and update design criteria. Under special
conditions, consideration can be given to deviating from
these standards. In those situations, the designer bears the
responsibility for any deviation and, therefore, should be
careful to consider all ramifications. Accordingly, each of
the criteria definitions in this monograph is preceded by a
discussion of the underlying considerations to explain the
basis of the criterion. This serves as a guide in appraising the
wisdom of deviating from a particular criterion for special
conditions.
The line of the upstream side of the dam or the line of the
coronet of the dam if the upstream side in slanting, is
considered as the orientation line for plan purposes, etc. and
is known as the “Base line of the Dam” or the “Axis of the
Dam”. When appropriate circumstances are on hand, such
dams can be constructed up to immense heights. The ratio of
base width to height of high gravity dams is generally less
than 1:1. A typical cross-section of a high concrete gravity
dam is shown in figure alongside. The upstream face may be
kept throughout perpendicular or partially slanting for some
of its length. A drainage passage is usually provided in order
to lessen the uplift pressure formed by the seeping water.
Purposes valid to dam creation may include routing, flood
damage reduction, hydroelectric power creation, fish and
wildlife improvement, water superiority, water supply, and
amusement. Several concrete gravity dams have been in use
for more than five decades, and over this phase significant
advances in the methodologies for assessment of natural
phenomena hazards have caused the design-basis events for
these dams to be revised upwards. Older existing dams may
fail to meet revised safety criteria and structural
rehabilitation to meet such criteria may be costly and
difficult.
8. Causes of Dam Failures
The incident of failures demonstrates that depending on the
type of dam, the cause of failure may be classified as:
a) Hydraulic failures; (for all types of dams)
b) Failures due to seepage.
(i) Through foundation, (all except arch dams)
(ii) Through body of dam (embankment dam)
c) Failures due to stresses developed within structure.
Arch dams fail instantaneously, whereas the gravity dams
take some multiples of 10minutes. A study of dam failures
in the world has revealed the percentage distribution ofdam
breaks and its attributes cause of failure.
1. Foundation problems 40 %
2. Inadequate spillway 23 %
3. Poor construction 12 %
4. Uneven settlement 10 %
5. High pore pressure 5 %
6. Acts of war 3 %
7. Embankment slips 2 %
8. Defective materials 2 %
9. Incorrect operations 2 %
10. Earthquakes 1 %
Other surveys of dam failure have been cited by, who
estimated failure rates from 2×10–4
to 7 × 10–4
per dam year
based on these surveys.
Paper ID: ART20199058 10.21275/ART20199058 2023
4. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
9. Sliding Failures
Sliding failures more often result from deficiencies in the
foundation. Various foundation conditions can make a
concrete dam vulnerable to sliding failure:
Low foundation shear strength
Bedding planes and joints containing weak material, such as
clay or bentonite Seams of pervious material, if seepage
through them is not controlled to prevent detrimental uplift
Faults and shear zones
Bedding planes and joints frequently have caused problems
at dam sites and therefore warrant close examination. Two
common types that have been troublesome are bedding plane
zones in sedimentary rocks and foliation zones in
metamorphic.
For a gravity dam, the potential for sliding may be greatest
when the foundation rock is horizontally bedded,
particularly where there is low shear strength along the
bedding planes. Consideration also must be given to zones
within the foundation rock that are especially susceptible to
the development of unacceptable seepage uplift forces.
A situation that can lead to detrimental uplift is the dam
tends to move downstream, tensile stresses are created in the
foundation which may cause upstream joints and cracks to
open and allow seepage to enter. The resulting uplift can
lead to sliding or overturning.
10. Overturning Failures
Overturning failures have various causes:
Insufficient weight or improper distribution of weight in the
dam cross section to resist the applied forces. This situation
can cause high compressive stresses at the toe of the
structure and/or high tensile stresses at the heel. Crushing of
the concrete or foundation material at the toe may occur as a
result of the high compressive stresses.
Tensile cracking over portions of the base of the structure
which is not in compression, resulting in high uplift forces
and a loss of resistance to overturning.
Erosion of the rock foundation at the toe of the dam due to
overtopping or rock deterioration.
High uplift pressures caused by inadequate seepage control
or pressure relief.
Excessive hydrostatic pressures due to severe flood
conditions, resulting in higher reservoir levels than the dam
was designed to accommodate.
11. Defective or Inferior Concrete
Substandard concrete may result from using inferior
materials or procedures in preparing or placing the concrete.
Inferior concrete may result from many causes, including:
Poor consolidation and curing Poor bond at lift lines
Weak aggregates Mineral-laden water
Highly absorptive aggregates, which may be susceptible to
freeze-thaw damage Aggregates contaminated by soils, salts,
mica, or organic material
High cement content, leading to high internal temperatures
due to hydration Insufficient pre or post cooling of concrete
High water/cement ratios in concrete mix
Lack of entrained air
Reactive aggregates
Many gravity dams built in the nineteenth century were
constructed of stone masonry with lime mortar. Lime mortar
is susceptible to deterioration and loss of strength over long
periods of exposure to seeping water. Once the bond
between stones created by the mortar has been broken, water
may enter the joints and the resulting pressure can cause a
sliding or overturning failure.
12. Concrete Distress
Cracking of concrete structures may result from excessive
tensile or compressive stresses, high impact loads such as
barges or ice, or differential movements of foundation and
abutment materials. In spillways or outlet works conveying
high velocity flows, offsets in the concrete surfaces may
cause cavitation. Vibration of structures by earthquake,
water surges, or equipment operation may also damage
concrete.
13. Foundation Failures
A seismic analysis must consider not only the effects of
ground motions on the structure, but also their impact upon
the strength of the foundation and abutments. Two main
types of foundation failure need to be considered:
Deformation, settlement, and fault movement Liquefaction
The dynamic strength of bedding planes and shear zones in
the foundation is usually lower than their static strength.
During earthquakes, movements can occur along faults or
other weak zones in the foundation and abutments. These
movements can cause a variety of problems:
1) Excessive movements can cause tensile cracking in the
dam, which could possibly lead to dam failure.
2) Excessive movements can open up faults and cracks in
the foundation, which may result in increased seepage
and a corresponding rapid increase in uplift pressures.
3) Infiltration of water along bedding planes due to open
cracks and fissures can cause reduced foundation shear
strength. For gravity dams, the potential for sliding is
greatest when the bedding planes are horizontal or they
dip in the upstream direction.
4) Infiltration of water along bedding planes can lead to
erosion of joint filler or shear zone material by piping.
5) This process can cause strength reduction as well as lead
to large settlements or undermining of the dam.
14. Uplift Pressures
Modern dams are designed assuming full uplift over 100
percent of the base area. Some older dams were designed
assuming that full uplift acted over only a percentage of the
Paper ID: ART20199058 10.21275/ART20199058 2024
5. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
base area, and this assumption has been found to be in error.
However, many dams designed under the older criteria have
performed satisfactorily, for several reasons:
Pressure levels may be less than assumed in the original
design because of good drainage or permeability of the
foundation.
It takes many years to saturate concrete and dense
foundation rock.
The reservoir may be at full pool conditions only for short
periods.
The fact that the resultant falls outside the middle one-third
of the base may not mean the dam is unstable.
There are sufficient uplift data to ensure that the uplift
(magnitude and distribution) used in the stability analysis is
representative of actual conditions for both the long and
short term.
High hydrostatic pressures are not present in rock zones
below the dam.
The instrumentation is functioning properly.
15. General Dimensions
For uniformity within the Bureau of Reclamation, certain
general dimensions have been established and are defined as
follows:
The structural height of a concrete gravity dam is defined as
the difference in elevation between the top of the dam and
the lowest point in the excavated foundation area, exclusive
of such features as narrow fault zones. The top of the dam is
the crown of the roadway if a roadway crosses the dam, or
the level of the walkway if there is no roadway. Although
curb and sidewalk may extend higher than the roadway, the
level of the crown of the roadway is considered to be the top
of the dam. The hydraulic height, or height to which the
water rises behind the structure, is the difference in elevation
between the lowest point of the original streambed at the
axis of the dam and the maximum controllable water
surface. The length of the dam is defined as the distance
measured along the axis of the dam at the level of the top of
the main body of the dam or of the roadway surfaces, on the
crest, from abutment contact to abutment contact, exclusive
of abutment spillway; provided that, if the spillway lies
wholly within the dam and not in any area especially
excavated for the spillway, the length is measured along the
axis extended through the spillway to the abutment contacts.
The volume of a concrete dam should include the main body
of the dam and all mass concrete appurtenances not
separated from the dam by construction or contraction joints.
Where a power plant is constructed on the downstream toe
of the dam, the limit of concrete in the dam should be taken
as the downstream face projected to the general excavated
foundation surface.
Forces Acting on a Gravity Dam
Fundamentally a gravity dam should satisfy the following
criteria:
1) It shall be safe against overturning at any horizontal
position within the dam at the contact with the
foundation or within the foundation.
2) It should be safe against sliding at any horizontal plane
within the dam, at the contact with the foundation or
along any geological feature within the foundation.
3) The section should be so proportional that the allowable
stresses in both the concrete and the foundation should
not exceed.
Safety of the dam structure is to be checked against possible
loadings, which may be classified as primary, secondary or
exceptional. The classification is made in terms of the
applicability and/or for the relative importance of the load.
1) Primary loads are identified as universally applicable
and of prime importance of the load.
2) Secondary loads are generally discretionary and of
lesser magnitude like sediment load or thermal stresses
due to mass concreting.
3) Exceptional loads are designed on the basis of limited
general applicability or having low probability of
occurrence like inertial loads associated with seismic
activity.
Technically a concrete gravity dam derives its stability from
the force of gravity of the materials in the section and hence
the name. The gravity dam has sufficient weight so as to
withstand the forces and the overturning moment caused by
the water impounded in the reservoir behind it. It transfers
the loads to the foundations by cantilever action and hence
good foundations are pre requisite for the gravity dam.
The forces that give stability to the dam include:
1) Weight of the dam
2) Thrust of the tail water
The forces that try to destabilize the dam include:
1) Reservoir water pressure
2) Uplift
3) Forces due to waves in the reservoir
4) Ice pressure
5) Temperature stresses
6) Silt pressure
7) Seismic forces
8) Wind pressure
The forces to be resisted by a gravity dam fall into two
categories as given below:
1) Forces, such as weight of the dam and water pressure
which are directly calculated from the unit weight of
materials and properties of fluid pressure and
2) Forces such as uplift, earthquake loads, silt pressure and
ice pressure which are assumed only on the basis of
assumptions of varying degree of reliability. In fact, to
evaluate this category of forces, special care has to be
taken and reliance placed on available data, experience
and judgement.
Paper ID: ART20199058 10.21275/ART20199058 2025
6. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
For consideration of stability of a concrete dam, the
following assumptions are made:
1) That the dam is composed of individual transverse
vertical elements each of which carries its load to the
foundation without transfer of load from or to adjacent
elements. However, for convenience, the stability
analysis is commonly carried out for the whole block.
2) That the vertical stress varies linearly from upstream face
to the downstream face on any horizontal section.
The Bureau of Indian Standards code IS 6512-1984 “Criteria
for design of solid gravity dams” recommends that a gravity
dam should be designed for the most adverse load condition
of the seven given type using the safety factors prescribed.
Depending upon the scope and details of the various project
components, site conditions and construction programme
one or more of the following loading conditions may be
applicable and may need suitable modifications. The seven
types of load combinations are as follows:
1) Load combination A (construction condition): Dam
completed but no water in reservoir or tailwater
2) Load combination B (normal operating conditions): Full
reservoir elevation, normal dry weather tail water,
normal uplift, ice and silt (if applicable)
3) Load combination C: (Flood discharge condition) -
Reservoir at maximum flood pool elevation, all gates
open, tailwater at flood elevation, normal uplift, and silt
(if applicable)
4) Load combination D: Combination of A and earthquake
5) Load combination E: Combination B, with earthquake
but no ice
6) Load combination F: Combination C, but with extreme
uplift, assuming the drainage holes to be Inoperative
7) Load combination G: Combination E but with extreme
uplift (drains inoperative)
It would be useful to explain in a bit more detail the different
loadings and the methods required to calculate them.
16. Methodology and Design of High Gravity
Dam
Check the stability of Typical section of gravity dam as
shown in fig.2. For reservoir empty and full condition
considering seismic forces assume reasonable value of uplift
and a line of drain holes 6m downstream of the upstream
face for the purpose of this check assume water level at the
top of dam and no tail water. Also find principal and shear
stresses at the toe & heel of dam. Take unit weight of
concrete23.5kN/m³ shear strength of concrete as 2200 kN/m²
and μ=0.7.The Specific Weight of Water is 9.81 kN/m³.
The allowable compressive stress 3000 kN/m² of dam
material is exceeds for concrete, the dam may crush and fail
by crushing. The maximum permissible tensile stress for
high concrete gravity dam under worst loadings may be
taken as 500 kN/m².
(i) Stability check of Concrete Gravity dam without
considering seismic forces
Case I: Reservoir Empty Condition
Calculation of stresses
When reservoir is empty only self-weight of dam will be
acting as force. Other forces such as water pressure & uplift
forces will be zero. The resulting force 𝛴𝑉1 and resulting
moment 𝛴𝑀1 for this case has worked out as follows:
(i.e. The Resultant acts nearer the heel and slight tension will
develop at the toe.)
Normal compressive stress at heel
𝑃𝑣𝑎𝑡 ℎ𝑒𝑒𝑙 = 2083.77 kN/m2
< 3000 𝑘𝑁/m2
(safe)
Normal compressive stress at toe
𝑃𝑣𝑎𝑡 𝑡𝑜𝑒 = 124.22 kN/m2
< 500 𝑘𝑁/m2
(safe)
Paper ID: ART20199058 10.21275/ART20199058 2026
7. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
Principal stress at heel
𝜎ℎ = 𝑃𝑣 sec² 𝜃; (tan 𝜃 = 0.063)
sec² 𝜃 = 1 + tan² 𝜃 = 1 + 0.0039 = 1.0039
= 2083.77x1.0039 = 2091.89 kN/m2
Which is < 3000 𝑘𝑁/m2
(𝑠𝑎𝑓𝑒)
Shear stress at toe
𝜏 = 𝑃𝑣 𝑡𝑎𝑛∅ = 124.22 × 0.70 = 86.95 kN/m²
Shear stress at heel
τ = 𝑃𝑣 tanθ = 2083.77x 0.063 = 131.28 kN/𝑚2
Case II: - Reservoir Full with No Uplift
Calculation of stresses
When reservoir is full, self-weight of dam and water
pressure will be acting as force. Other force such as uplift
forces will be zero. The resulting force 𝛴𝑉2 and resulting
moment 𝛴𝑀2 for this case has worked out as follows:
Position of resultant from toe
X =
∑M2
∑V2
=
2195899.52
78824.40
= 27.86 m
Position of resultant from the centre of the base is
e =
B
2
− X =
69.5
2
− 27.86 = 6.89 m
(i.e. The Resultant acts nearer the toe and tension will
develop at the heel.)
Normal compressive stress
𝑃𝑚𝑎𝑥 /𝑚𝑖𝑛 =
∑𝑉2
B
1 ±
6𝑒
B
=
78824.40
69.5
1 ±
6𝑥6.89
69.5
Normal compressive stress at toe
𝑃𝑣𝑎𝑡 𝑡𝑜𝑒 = 1808.79 kN/m2
< 3000 𝑘𝑁/m2
(safe)
Normal compressive stress at heel
𝑃𝑣𝑎𝑡 ℎ𝑒𝑒𝑙 = 459.54 kN/m2
< 500 𝑘𝑁/m2
(safe)
Principal stress at toe
𝜎𝑡 = 𝑃𝑣 sec² ∅; (tan ∅ = 0.7)
= 1808.79 1 + 0.49 = 2695.09 kN/m2
Which is < 3000 𝑘𝑁/m2
(safe)
Principal stress at heel
𝜎ℎ = 𝑃𝑣 sec² 𝜃 − 𝑃 𝑡𝑎𝑛²𝜃
(𝑡𝑎𝑛 𝜃 = 0.063);
sec² 𝜃 = 1 + tan² 𝜃 = 1 + 0.0039 = 1.0039
= 459.54x1.0039 − 9.81x95 x0.0039
= 455.84 kN/m2
Which is < 500 𝑘𝑁/m2
(𝑠𝑎𝑓𝑒)
Shear stress at toe
𝜏 = 𝑃𝑣 𝑡𝑎𝑛∅ = 1808.79 × 0.70 = 1266.15 kN/m²
Shear stress at heel
τ = − 𝑃𝑣 − P tanθ
= − 459.54 − 9.81x95 x 0.063
= 29.76 kN/𝑚2
The factor of safety against sliding and overturning should
be found out only when reservoir is full &Full uplift acts,
since the condition of sliding & overturning will be more
critical in that case.
Case III: Reservoir Full with Uplift
Calculation of stresses
When reservoir is full, including self-weight of dam and
water pressure, &uplift forces will be acting as forces. The
resulting force 𝛴𝑉3 and resulting moment 𝛴𝑀3 for this case
has worked out as follows:
Position of resultant from toe
X =
∑M3
∑V3
=
1451892.56
64068.52
= 22.66 m
Position of resultant from the centre of the base is
e =
B
2
− X =
69.5
2
− 22.66 = 12.09 m
(i.e. The Resultant acts nearer the toe and tension will
develop at the heel.)
Normal compressive stress
𝑃𝑚𝑎𝑥 /𝑚𝑖𝑛 =
∑𝑉3
B
1 ±
6𝑒
B
=
64068.52
69.5
1 ±
6𝑥12.09
69.5
Normal compressive stress at toe
𝑃𝑣𝑎𝑡 𝑡𝑜𝑒 = 1884.02 kN/m2
< 3000 𝑘𝑁/m2
(safe)
Normal compressive stress at heel
𝑃𝑣𝑎𝑡 ℎ𝑒𝑒𝑙 = −40.32 kN/m2
< 500 𝑘𝑁/m2
(safe)
Principal stress at toe
𝜎𝑡 = 𝑃𝑣 sec² ∅; (tan ∅ = 0.7)
= 1884.02 1 + 0.49 = 2807.19 kN/m2
Which is < 3000 𝑘𝑁/m2
(safe)
Principal stress at heel
𝜎ℎ = 𝑃𝑣 sec² 𝜃 − 𝑃 𝑡𝑎𝑛²𝜃
(𝑡𝑎𝑛 𝜃 = 0.063) ;
sec² 𝜃 = 1 + tan² 𝜃 = 1 + 0.0039 = 1.0039
= 40.32x1.0039 − 9.81x95 x0.0039
= 36.84 kN/m2
Which is < 500 𝑘𝑁/m2
(𝑠𝑎𝑓𝑒)
Shear stress at toe
𝜏 = 𝑃𝑣 𝑡𝑎𝑛∅ = 1884.02 × 0.70 = 1318.81 kN/m²
Shear stress at heel
τ = − 𝑃𝑣 − P tanθ
= − 40.32 − 9.81x95 x 0.063
= 56.17 kN/𝑚2
Paper ID: ART20199058 10.21275/ART20199058 2027
8. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
Calculation of Factor of Safety
(ii) Stability check of Concrete Gravity dam by
considering seismic forces:
For worst condition consider that,
i) Horizontal earthquake acceleration acts upstream.
ii) Vertical earthquake acceleration acts downwards.
Hydrodynamic pressure due to water caused by earthquake
can be found out from zangers formula. Since the slope is
upto middle depth, approximate value of θ can be found out
by joining heel to the upstream edge.
Calculation of 𝐏𝐞:
Pe and the moment due to this hydrodynamic force is
calculated and then all the forces and their moments are
tabulated in table 1.1
Calculation of 𝐏𝒆 from Zanger’s formulas
Pe= 0.726 𝑝𝑒H
Where𝑝𝑒 = Cm αhγw H
tan θ = 95/3 = 31.66 or θ = 88.19°
Cm = 0.735x
88.19°
90°
= 0.72
At base C = Cm
Therefore 𝑝𝑒 = Cm αhγw H
As per IS: 1893-1984, Clause 3.4.2.3
𝛼ℎ = 𝛽𝐼𝛼𝑂
𝛽 = 1.00 for Dams (As per IS: 1893-1984, Clause 3.4.3,
from Table 3)
𝐼 = 3.00 for dams (all types) (As per IS:1893-1984, Clause
3.4.2.3 and 3.4.4, from Table 4)
(As per IS: 1893-2002, Clause 3.4.2.1,3.4.2.3 and 3.4.5,
from Table 2)
𝛼𝑂=0.04for zone III in seismic coefficient method
∴𝛼ℎ =1.00×3.00×0.04=0.12
As per IS: 1893-1984, Clause 7.3.1.1, 7.3.1.2 Concrete or
masonry inertia force due to horizontal and vertical seismic
acceleration Seismic coefficient method (dams up to 100 m
height)
Horizontal seismic coefficient shall be taken as 1.5 times
seismic coefficient𝛼ℎ at the top of the damreducing linearly
to zero at the base.
Vertical seismic coefficient shall be taken as 0.75 times the
value of 𝛼ℎ at the top of the dam reducinglinearly to zero at
the base.
The value of 𝛼ℎ (horizantal) = 1.5× 0.12 = 0.18
and 𝛼𝑣(vertical) = 0.75× 0.12 = 0.09
𝑝𝑒 = Cm αhγw H
Substitute 𝐶𝑚 and 𝛼ℎ value in above equation
𝑝𝑒 = 0.72𝑥0.18𝑥9.81𝑥95 = 120.78 kN/m2
Total pressure Pe= 0.726 𝑝𝑒H
Pe = 0.726𝑥120.78𝑥95 = 8330.20 kN
Moment due to this force at base,
Me = 0.412 Pe H = 0.412 x 8330.78 x 95
= 326066.73 kNm
When the reservoir full with all forces including uplift
Horizontal seismic forces moving towards the reservoir
causing upstream acceleration, and thus producing
horizontal forces towards downstream is considered, as it is
the worst case for this condition. Similarly, a vertical
seismic force moving downward and thus, producing forces
upward, i.e., subtractive to the weight of dam is considered.
Calculation of forces and moments due to inertial earthquake
force is done below: -
Additional forces and their moments due to earthquake
Position of resultant from toe
X =
∑M4
∑V4
=
702268.08
57163.04
= 12.29 m
e =
B
2
− X =
69.5
2
− 12.29 = 22.46 m
The resultant is nearer the toe and tension is developed at the
heel.
Average vertical stress
Normal compressive stress
Paper ID: ART20199058 10.21275/ART20199058 2028
9. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
𝑝𝑣 at toe = 822.49 x2.94 = 2418.12 kN/m2
Which is <3000 kN/m2
(safe)
𝑝𝑣 at heel = - 822.49x 0.94 = -773.14 kN/m2
Which is <500 kN/m2
(safe)
Since the tensile stress developed is less than the safe
allowable value, the dam is safe even examined with seismic
forces, under reservoir full condition.
Principal stress at toe
𝜎𝑡 = 𝑃𝑣 sec² ∅; (tan ∅ = 0.7)
= 2418.12 1 + 0.49 = 3602.99 kN/m2
Which is > 3000 kN/m2
(unsafe)
Principal stress at heel
𝜎ℎ = 𝑃𝑣 sec² 𝜃 − 𝑃 𝑡𝑎𝑛²𝜃
(𝑡𝑎𝑛 𝜃 = 0.063) ;
sec² 𝜃 = 1 + tan² 𝜃 = 1 + 0.0039 = 1.0039
= −773.14x1.0039 − 9.81x95 x0.0039
= −779.79 kN/m2
Which is < 500 𝑘𝑁/m2
(𝑠𝑎𝑓𝑒)
Shear stress at toe
𝜏 = 𝑃𝑣 𝑡𝑎𝑛∅ = 2418.12 × 0.70 = 1692.68 kN/m²
Shear stress at heel
τ = − 𝑃𝑣 − P tanθ
= − −773.14 − 9.81x95 x 0.063
= 107.42 kN/𝑚2
Calculation of Factor of Safety
(i) Factor of safety against overturning
Hence unsafe
(ii) Factor of safety against sliding
Hence unsafe
(iii) Shear friction factor
Hence unsafe
(iv) Safety against sliding as per IS 6512-1984
Taking 𝑓∅ =1.5 &𝑓𝑐 =3.6 for loading combination B,
Hence unsafe
17. Observations and Results
18. Conclusion
The behaviour of Gravity dam for stability and response
towards seismic forces are studied in this paper. With
problem consideration the stability analysis of gravity dam is
done in absence of seismic forces initially. Thus, analysis
highlighted that in presence of various loads like dead load,
water/ hydrostatic pressure, uplift pressure, total cumulative
values of +ve moment and -ve moment, summation of
horizontal and vertical forces are overall responsible for dam
stability. Further with analysis it is clear that moment
Paper ID: ART20199058 10.21275/ART20199058 2029
10. International Journal of Science and Research (IJSR)
ISSN: 2319-7064
ResearchGate Impact Factor (2018): 0.28 | SJIF (2018): 7.426
Volume 8 Issue 6, June 2019
www.ijsr.net
Licensed Under Creative Commons Attribution CC BY
resulting due to self-weight act as resistive moment against
moment produced due to water, uplift pressure etc. Which
means that stability against overturning is achieved when
+ve moment is greater than -ve moments. Whereas stability
against sliding depends upon coefficient of friction, sum of
all vertical forces and all horizontal forces. Thus, sliding is
governed by uplift pressure. More friction coefficient &
more summation of vertical forces results stability against
sliding. However, if horizontal force increases stability
against sliding decreases if vertical forces remain
approximately same. Third stability of dam is on basis of
shear friction factor, this depends upon coefficient of
friction, summation of all vertical forces, summation of all
horizontal forces, geometry of dam and materials shear
strength. For same problem material shear strength,
geometry friction remains unchanged, thus stability should
depend upon sum of all vertical forces and all horizontal
forces. For problem considered in study, dam achieves
stability against all factors i.e. overturning, sliding
&shearing. The dam is unsafe only sliding and S.F.F., for
which shear key etc. can be provided.
References
[1] Bureau of Indian standards publication IS: 1893-1984
criteria for Earthquake Resistant design of structures.
[2] Seismic analysis for safety of dams, IOSR journal of
civil engineering, vol 6, 2013.
[3] IS: 6512-1984 criteria for design of solid gravity dams.
[4] Irrigation water resources and water power engineering
by B.C Punmia.
[5] Irrigation Engineering and Hydraulic Structures by
Santosh Kumar Garg
[6] Dr. D.S Saini (1983), “Dams and Earthquake”.
Department of civil engineering, University of Roorkee.
[7] Earthquake Tips (C.V.R. MURTHY, Dept. of Civil
Engg. IIT Kanpur)
[8] H.D Sharma (1981) “concrete Dams – Criteria for
Design.” University of Roorkee. Metropolitan
publication New Delhi.
Author Profile
Er Venkata Raju Badanapuri, Executive Engineer,
Water Resources Department, Government of Andhra
Pradesh, India. His educational Qualifications includes
Institute of Engineers India, C.E (India), F.I.E. He did
Post-Graduation in M. Tech (Structural Engineering), J.N.T
University, Hyderabad. He did B.E.(Civil), Andhra University,
Vishakhapatnam. He has following Journal Publications in his
name:
1. “Indian Scenario of Water Resources - An Overview, Integrated
Water Management and Major Issues related to Indian Waters " in
ISSN:2321-7758, Vol.6., Issue.5, 2018 Sept-Oct., PP 64-70,
International Journal of Engineering Research by Venkata Raju
Badanapuri
2. “An Overview of Integrated theory of Irrigation Efficiency and
Uniformity and Crop Water Use Efficiency Indian Waters " in
ISSN:2321-7758, Vol.6., Issue.6, 2018 Nov-Dec., PP 11-26,
International Journal of Engineering Research by VenkataRaju
Badanapuri
3. “Water Resources Scenario in India: Its Requirement,
WaterDegradation and Pollution, Water Resources Management”
ine-ISSN:2348-6848, Volume 05 Issue 23December 2018,PP 672-
696,International Journal of Researchby VenkataRaju Badanapuri
Paper ID: ART20199058 10.21275/ART20199058 2030