All posts by Vinod Gopinath

dams, Hydrauilics

Reservoir vs Dams || Reservoir- Types and functions

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Reservoirs are artificial or natural structures used for collecting and storing for further usages. The reservoir is formed by constructing dams across rivers, valleys, and streams. The Reservoir is located on the upstream side of dams and prevents floods by managing the water flow apart from serving as a storage basin.

Also Read : Types of Dams – 3 Classification Criteria Explained.

Also Read : Components of a bridge – Types and Functions Explained

Functions of Reservoirs

Reservoirs are man made lake or a fresh water body that plays an important role a lot of ways as listed below.

  • Water supply
  • Flood control
  • Environmental management
  • Hydroelectric power management
  • Navigation
  • Irrigation
  • Development of fish and wildlife
  • Soil conservation
Reservoir behind dam
Reservoir behind dam

Also Read : Components of a dams-12 Dam Components explained.

Types of reservoirs

Reservoirs are broadly classified into three types.

  • Valley dammed reservoirs
  • Back-side reservoirs
  • Service reservoirs

Valley dammed reservoirs

Valley dammed reservoirs are located between mountain valleys where there is an existing water body. A dam is built in the narrowest portion for holding the water.

Bank-side reservoirs

Bank side reservoirs are made by diverting water from rivers and streams to an existing reservoir. These reservoirs can be located in different geographical locations.

Service reservoirs

Service reservoirs are man made reservoirs located above the ground or below the ground. The huge water towers/ water tanks and sumps are service reservoirs.

Service Reservoir
Service reservoir

Reservoir components and terms

There are some specific terms for defining the water level and storage capacity of a reservoir

Pool level

The water level at a particular point of time is called the pool level. No water can be collected above the maximum pool level. No water can be drained below the minimum pool level.

Useful Storage

The volume of water within the normal pool level and minimum pool level is known as useful storage.

Dead storage

The volume of water underneath the minimum pool level is known as dead storage.

Surcharge Storage

The volume of water within the normal pool level and maximum pool level is known as surcharge storage.

Reservoir yield

The volume of water discharged within a certain interval of time is reservoir yield.

Reservoir Planning

Accurate planning is necessary for locating a reservoir. For planning a reservoir the following points are taken into consideration.

Topography

A Broad natural valley opts as the site of a reservoirs. The valley can be U- shaped or V-shaped. For reservoirs sites, flatland and plains are not considered.

Ground water condition

The groundwater investigation is done by analysing the water table level and reservoir level.Hence it is an ideal situation for the reservoirs site if the water table level and the top reservoir level is the same. No loss or gain is ensured.

Permeability

Permeability is a default nature as the rocks are porous. It is considered when the water table is below the reservoirs level. It is a significant characteristic for investigation.

Hydrological Investigation

This involves the study of runoff pattern. Leakage quantity should be minimum. Storage capacity calculation and maximum discharge rate are also estimated.

Difference between dams and reservoirs

DAMSRESERVOIR
Structural barriers built across,rivers
valleys,streams etc for the purpose of
storing and managing water flow.		Reservoir is a large water body formed behind the constructed dam structure across a river,stream,etc
Dams are reinforced concrete structures or structures made of bricks rubble etc erected across water bodies to control the water flow.The reservoir is the water that accumulates behind the constructed dam.
Create site for hydro electric power generation. This can improve the industrial development and living standards of people living in that region.Stores water for later usage, water for human consumption and excess water for agricultural and industrial uses.
Dams fluctuates oxygen levels and restricts migration of fishes in the river.Reservoirs leads to the displacement of people.
Dams are tourist attraction sitesHelps in water transportation

Reservoir Sedimentation

Rivers transport sediments. During heavy rainfall, sediments are carried by the water to the reservoir. Silts are accumulated due to soil erosion. These get collected in the dead storage.
Sedimentation depends on Rainfall intensity, Soil nature, Soil type, topography and vegetation. The sediment deposit replaces the water storage. Thus water supply and flood control are affected.
The sediments should be removed eventually. Hydraulic flushing, dredging, Explosive mobilization are methods adopted for sedimentation removal.

Reservoir
reservoir

Environmental impacts of Reservoirs.

  • The construction of the reservoir prompts severe effects on the environment.
  • Since the water is stored, the rate of transpiration is high. This changes the moisture concentration.The climate of the surrounding area is affected. It causes natural temperature fluctuation. This causes heavy rainfall and deprives the traditional rainfall patterns.
  • Reservoirs disturb the flow and composition of the rivers. The water from the downstream has high energy, it enhances the water flow by eroding the river bed.
  • The change in the river composition affects the upstream and downstream habitats. The reservoirs disturb the fish and birds migration.
  • Studies show that reservoirs emit greenhouse gases. Anaerobic bacterias are seen in the river bed releases carbon dioxide and methane. This occurs in tropical regions.
  • They also cause troubles for people living near the reservoir site. Old and failing dams lead to disasters.
  • Reservoir induced seismicity is a phenomenon of provoking earthquake by reservoirs. This happens when water sweeps into the minor cracks under the bed.
civil engineering, Total station

Total station in surveying– Working Principle of Total station

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Total station in surveying is used for computing slant distances, horizontal and vertical angles, elevations in topographic and geodetic works, tacheometric surveys, etc. The total station is a pre-eminent contribution to modern surveying and hence the equipment is designed for speed, range, and accuracy. They are a combination of Theodolite and Electronic Distance measurement (EDM). This enables computing the vertical, horizontal as well as slope measurements.

They act as a substitute for theodolite, EDM, Data collectors, and Microprocessors. Moreover, they are lightweight and compact machines and perform like transit stadia and plane table alidades.

The integration of microprocessors helps in the data collection and measurement computation process. Further to that, the inbuilt software helps to generate the maps instantly.

  1. Applications of Total station
  2. Working Principle of Total station
  3. Major components of Total station
  4. Total station applications
    1. Distance measurement
    2. Angular measurement
    3. Data processing 
  5. Setting up of a total station
  6. Advantages of Total station
  7. Disadvantages of Total station
  8. Key Takeaways
  9. Conclusion

Applications of Total station

Apart from taking the measurements, the total station helps in computing, interpreting, and documenting the data. Here is a list of activities that are computed, interpreted, and analyzed.

Total station
Total station
  • Horizontal angle
  • Vertical angle
  • Slope distance
  • Coordinate of point
  • Missing line measurement
  • Area calculation
  • Contour level

Working Principle of Total station

The total station consists of a built-in emitter, capable of emitting microwaves and infrared signals. The wavelength of these emitted waves helps in calculating the distance between the points.
Distance = velocity * time 

Here the distance is calculated by multiplying the time taken to cover a certain distance by the velocity. However, Triangulation and trigonometry methods are adopted for computing the angles and determining the coordinates.

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Major components of Total station

The Equipment is composed of different parts. Below listed are the major components.

Components of total station
Components
Components of total station
Components of total station
  • Handle
  • Handle securing screw
  • Data input/output terminal (Remove handle to view)
  • Instrument height mark
  • Battery cover
  • Operation panel
  • Tribrach clamp
  • Baseplate
  • Levelling foot screw
  • Circular level adjusting screws
  • Circular level
  • Display
  • Prism and prism pole
  • Objective lens
  • Tubular compass slot
  • The optical plummet focusing ring
  • Optical plummet reticle cover
  • Optical plummet eyepiece
  • Horizontal clamp
  • A horizontal fine motion screw
  • Data input/output connector
  • External power source connector
  • Plate level
  • Plate level adjusting screw
  • Vertical clamp
  • A vertical fine motion screw
  • Telescope eyepiece
  • Telescope focusing ring
  • Peep sight
  • Instrument centre mark

A tripod enables one to affix the equipment onto the ground. A handle is available on the top of the equipment for holding it. There are a Data input and output terminal below the handle enabling the data transfer to the computer.
The total station comes with inbuilt software, an operation panel, a keyboard, and a screen. The prism and prism poles help in measuring distances.

Total station applications

The total station consists of an EDM, Theodolite, and a Microprocessor combined into one. They got a memory card for data storage and a battery. A fully charged battery works for about 3 to 5 hrs continuously.

  • Coordination determination
  • Distance measurement
  • Angular measurement
  • Data processing
  • Coordination Determination

The total station determines the coordinate of an unknown point. The instrument is placed over a known coordinate. The equipment digitally computes the coordinates.

Distance measurement

As mentioned earlier, the total station got an inbuilt miniature emitter. The emitters release microwave signals. The prism reflector or object under survey at the other end reflects the waves. Onboard data interpreters compute the distance by emitting and receiving multiple frequencies.

Angular measurement

The total station uses the distance between the point and the time taken by the waves reflected for deciding angular measurement.

Data processing 

The integration of the microprocessor in a total station helps to read and interpret the survey parameters. Subsequently, the data is stored in the memory card of the instrument and later transferred to a computer. They can compute multiple measurements with high precision with compensation for temperature, pressure, and humidity corrections.

Setting up of a total station

  • The basic steps involved in setting up are tripod setup, levelling, and instrument focusing.
  • The tripod legs are placed firmly on the ground with equidistant legs with the head position above the survey point.
  • The total station is placed on the tripod. It is fixed and secured using a centring screw. 
  • The next step is to sharpen the optical plummet towards the survey point. On sharpening, the optical plummet reticle centres the survey point. 
  • The bubble is adjusted to the centre by levelling foot screws
  • The time taken for levelling the equipment depend on the skill of the operator. However, levelling is the topmost activity to maintain the accuracy of measurements.
  • Adjust the plate level by loosening the horizontal clamp. The equipment is parallel to levelling foot screw.
  • Turn the instrument at 90 degrees and level using a 3rd levelling screw.
  • Subsequently, turn on the instrument.
  • Select the tilt function from the opening window followed by adjusting the foot level screw and centre the bubble.
  • Rotate the instrument at 90 degrees. Repeat the process.
  • Finally, adjust the ring and focus the telescope on the target point.
Total station prism
Total station prism

Advantages of Total station

There are a lot of advantages of total station as mentioned below

  • High precision and accuracy.
  • Requires limited manpower 
  • Perform quick fieldwork
  • Reduction in manual errors.
  • Correction for temperature, pressure etc and digitally rectified. 
  • Storage and interpretation of data are easy
  • Time consumed is less.
  • Inbuilt GIS software helps in instant map creation
  • Assists in local languages.

Disadvantages of Total station

  • The cost of the instrument is high.
  • Need highly skilled surveyor with AutoCAD knowledge and professional training.
  • Checking errors during the operation is impossible.
  • Low battery life.

Key Takeaways

  1. Functionality: Total station integrates Theodolite and Electronic Distance Measurement (EDM) for precise surveying.
  2. Components: Includes emitter, microprocessor, prism, and multiple control interfaces.
  3. Applications: Measures horizontal/vertical angles, distances, coordinates, and calculates areas/contours.
  4. Working Principle: Uses microwaves/infrared signals to compute distances via time and velocity; angles through triangulation and trigonometry.
  5. Advantages: High precision, reduced manual errors, quick data processing, minimal manpower, and inbuilt GIS software for instant mapping.
  6. Disadvantages: High cost, requires skilled operators, limited battery life, and no real-time error checking.
  7. Setup Process: Involves tripod positioning, levelling, centring optical plummet, and adjusting levels and focus.

Conclusion

The total station revolutionizes modern surveying with its advanced integration of theodolite, EDM, and microprocessor technology. It enhances efficiency through precise measurements, quick data processing, and inbuilt mapping capabilities. Despite its high cost and need for skilled operation, the total station’s benefits of high accuracy, reduced manpower, and minimized manual errors make it indispensable in topographic, geodetic, and tacheometric surveys. Its ability to handle multiple functions—angle, distance, and coordinate measurements—streamlines surveying tasks, making it a valuable tool for civil engineering and related fields.

architectural finishes, Water Proofing

Water proofing types – 5 effective methods explained.

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Water proofing is a method of applying coatings to a structure to make it waterproof or leak proof. Waterproofing is one of the most critical construction activities meant for enhancing the life and stability of the building/structure. In other words, we can say waterproofing means preventing the entry of water through a structure. This article is about the waterproofing methods suggested for residential, industrial, and commercial applications.

Why waterproofing is required?

Waterproofing is applied for basement or below-ground areas, toilet areas, swimming pools, water storage tanks, water retaining structures, rooftops and podium areas, deep industrial structures, foundations, etc.

  • Waterproofing is a must for basements below grade/ground level to prevent water seepage and structural damages. Basement waterproofing is unavoidable in areas where the water table is very high, and chances of rainwater flooding around the building and sweeping through the basement walls.
  • Concrete is a porous material and hence vulnerable to chemical attack. Water will enter and cause structural deterioration to the concrete and corrosion of embedded steel.
  • Rooftop and podium areas are exposed to rain and water seepage through concrete surfaces and cracks will damage the valuable interiors and embedded steel.
  • Waterproofing is a much-needed construction activity essential to maintain the life of the building.

Also Read : Ready mix plaster vs conventional plaster – comparison

Also read : Smart Building- 4 features full guide

Areas of water proofing

Water proofing is required in the following areas to prevent serious structural damage and enhance the durability and life of a building/structure.

  • Basement structure
  • Kitchen,toilet and other wet areas
  • Roof, terraces, balconies, podium, grass decks etc
  • Swimming pools and water retaining structures
  • Under ground tanks
  • Under ground industrial structures like wagon tipplers and track hoppers
  • Tunnels etc

Types of water proofing

Different waterproofing systems are suggested for different areas and locations depending upon the nature of water seepage expected.

They are classified on the basis of method adopted

  • Cementitious water proofing
  • Liquid water proofing membranes
  • Bituminous water proofing membrane
  • Bituminous coating
  • Polyurethane (PU) based water proofing membrane

Also read : Shotcrete – A total overview – Shotcrete vs gunite

Cementitious water proofing

Cementitious waterproofing is the most common and economical method of waterproofing used in construction works. The materials are readily available and can be mixed and applied with ease.

The cementitious waterproofing materials are available in various types.
Commonly used types are

  • Polymer modified Cementitious waterproofing
  • Acrylic polymer modified Cementitious coatings.
  • Crystalline water proofing

Polymer-modified cementitious waterproofing

Polymer-modified cementitious waterproofing systems are two-part cement-based polymer coatings that are highly flexible and elastic. Polymer-based coatings possess enhanced adhesion and are breathable. No vapor from concrete is entrapped inside. These types of coatings are preferred for waterproofing works in water storage tanks, basements, swimming pools, and pumping stations, and any other structures that are constantly in contact with water. These coatings are not preferred for waterproofing works exposed to sunlight.

Water proofing method - Application of cementitious membrane
cementitious coating

Acrylic polymer-modified cementitious coating

The acrylic polymer-modified cementitious coating is a single component /two-component material mixed with an acrylic polymer and special additives. The acrylic additives provide strong adhesion and a durable coating on any surface like steel, concrete, etc. The ingredients constitute cement-based materials that can easily blend with water or polymer emulsions. The acrylic polymer coatings are solid, durable, elastic, and nonbreakable.

Crystalline water proofing

Crystalline Cementitious Waterproofing systems consist of cement, quartz, or silica treated with and chemicals for the crystallization process. Once combined with water, it creates a crystalline structure that fills the pores, cracks, and capillaries in concrete which disallows water from seeping through them. This method of waterproofing is preferred for internal and external waterproofing of concrete structures.

Cementitious water proofing systems are not preferred for areas where there are structural cracks or any other moments.

Liquid-applied membrane

Liquid-applied membrane (LAM) is a monolithic, fully-bonded, liquid-based coating that cures to form a rubber-like elastomeric waterproof membrane. These are mainly used for roof waterproofing.
The coating is capable of stretching and returning to its original shape without damage. They can also be reinforced with materials like glass-reinforced plastic to enhance tensile strength.
Liquid waterproofing membranes provide a cost-effective method of making a new or existing roof waterproof. They are durable, flexible, and got excellent life of around 20 years without failure. The application is done using brushes or sprayed over a coat of appropriate primers. The main ingredient responsible for the properties is polymer-modified asphalt.

Polyurethane liquid based elastomeric membrane

Polyurethane waterproofing is a two-component material based on urethane pre-polymers and cures by reaction with atmospheric moisture to form a continuous elastic and rubbery film. Unlike other waterproofing systems like sheet membranes and liquid applied membranes, this polyurethane application requires comparatively less skill and supervision.
These membranes got excellent UV-resistant properties and got good adhesion to any surface like concrete, slate, tile, steel, etc. They are mainly used for roof applications.

Bituminous coating

Bituminous coating is a flexible coating used for structural protection and waterproofing of concrete foundations and exposed sides of underground exposed structures. The main ingredient of bituminous coatings is bitumen based material and anti-stripping agents. Bituminous coating is not preferred for works exposed to sunlight. On exposure, they will become brittle and peel off from the surface.

water proofing - Bituminous coating
Water proofing – Bituminous coating

Bituminous membrane or APP Membrane

water proofing - Bituminous membrane or APP membrane
Water proofing – AAP Membrane or torch applied membranes

APP membrane is a bituminous membrane modified with APP polymers. APP stands for Atactic Polypropylene and is manufacture from a plastic called atactic polypropylene and bitumen mix. These membranes are also called torch-applied membranes. During this process, the plastic begins to melt and form a wax-like liquid which is levelled on a surface.

Conclusion

The methods of waterproofing depends on the application areas and location of seepage. The locations, nature, economy, purpose of structure has to be technically studied and analysed before proposing an appropriate treatment method.

architectural finishes, Marble

Marble flooring – Advantages || Disadvantages – A complete analysis

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Marble is one of the most durable, elegant, and beautiful flooring materials used for centuries. Marble flooring is a superior quality flooring that can match any architecture concept and never get outdated. Apart from presenting luxurious interiors, the marble flooring can enhance the value of the building.

Despite being one of the best flooring options, marble stone got their disadvantages also. This article provides a fair knowledge about the advantages and disadvantages of marble stone flooring.

Must read : Vitrified tiles vs Ceramic tiles- How to choose a tile?

Must Read : Types of ceramic tiles – Advantages & Disadvantages

Composition of marble 

A sedimentary stone like limestone subjected to enormous heat and pressure for millions of years is transformed into a much harder stone with elegant color, swirls, and veined patterns. This process of transformation is known as metamorphosis and the natural stone developed through this process is known as marble stone. The marble is quarried and cut into slabs and tiles and used for applications like flooring, countertops, wall cladding, floor and wall tiles, antique pillars, etc.

Marble stone quarry

The veins and swirls present in many marble pieces occur when various mineral impurities like clay, silt, sand, iron oxides, etc mixed with the original limestone. On polishing, the marble looks elegant, smooth, reflects light, and feels the interior more spacious.

Also Read : AAC Blocks vs Red Bricks

Also Read : WPC vs Plywood – Which is best ?

Marble flooring stones – Types

Marble is a semi- transparent and soft natural stone. They have a tendency to penetrate and reflects lights, They are porous stone with a high water absorption rate, Marble flooring tiles come in varying colors and surface patterns. Here we are listing some of the popular types of marble stone available.

  • Makarana Marble
  • Italian Marble
  • Rajnagar White Marble
  • Ambaji Green Marble
  • Kesarayaji Green Marble
  • Udaipur Pink Marble
  • Udaipur Green Marble
  • Jaisalmer Yellow Marble
  • Abu black Marble
  • Aandhi Marble
Marble flooring

Marble flooring – Finishing

Marble floors/sculptures are finished in different patterns depending on the architecture concept and usage.

  • Polished marble
  • Honed finished marble

Polished marble

Polished marble is the most popular finishing option of marble flooring. The marble surface is ground with a stone polishing machine using a variety of stones. Polishing gives a smooth and high gloss look to the marble floor. Polishing exposes the veins and swirls in the marble and provides a classy, superior, and elegant look. Polished marble is less porous and very easy to maintain when compared to other finishes and able to retain the sheen and charm for many years.

Polished marble is very slippery and not preferred in areas where there are chances of any water presence.

b) Honed finish

Honey-finished marble is the lightly polished form of marble finishing done just enough to produce a minor glossiness. These are less slippery but they may not be scratch resistant. Maintenance is also a little bit difficult when compared to polished marble.

Advantages of marble flooring

Marble flooring is one of the most popular options and is available in a wide range of colors, textures, and patterns. They are durable, elegant, and gives a superior feel to the interiors. Despite all these enormous advantages marble got a bit of a disadvantage also. These parameters have to be taken into account while considering the option of flooring with marble stones.

a) Durability

Marble is a natural material and got a reputation for durability over hundreds of years now. Marble is extremely durable,scratch-free, and long-lasting and can withstand any traffic and external pressures, and weight changes. Apart from residential uses, they are suitable for high traffic areas like commercial buildings, hotels, institutions, etc.

b) Versatile Designs and natural elegance

Marble is available in different colors, veins, swirls, patterns, and shades and can match any color scheme of the space and the customer’s needs. No other natural stone is elegant as marble that gives a simple and natural look to any space. The patterns, color, and design vary slightly in each slab/tile resulting in a custom look for each tile/slab.

Marble flooring designs
Marble flooring designs

c) Translucent properties

Marble is a translucent, semi-transparent material that allows some light to pass through it. The shiny translucent marble surface reflects light and thereby enhances the amount of natural light present in the rooms. This makes the rooms brighter, open, and more spacious. Because of the translucent properties, white and light-colored marble is best for flooring works. White cement grouts are more suitable for marble laying instead of grey cement.

d) Ease of cleaning

The marble floor is seamless and smooth and hence can be cleaned easily using mild detergents and water. The maintenance cost of a marble floor is low when compared with tile or any other type of flooring.

e) Ease of cutting and moulding

Marble stones are soft and the exact size as can be cut, moulded and shaped very easily.

f) Eco-friendly material

Marble is an eco-friendly and natural material. No chemical process is involved in the manufacturing of marble. Marble is a completely degradable material.

g) Cool feeling on foot

Marble stone provides a cool feeling in hot climates.

h) Architect favourite

Marble flooring gives an excellent look when mirror polished and provides a significant aesthetic for interiors. Marble flooring can match any color scheme of the space. The light-reflective properties enhance the class of this product and hence preferred by architects and interior designers.

i) Heat conduction

Marble is a good conductor of heat and is an integral part of radiant, in-floor heating system . This can make us feel warm even in the coldest temperatures.

j) Antibacterial and anti allergic properties

Marble eliminates microscopic particles and germs if it is cleaned properly.

Disadvantages of marble flooring

Despite its beauty, elegance, durability, and classic looks marble has some disadvantages. Let us go through the disadvantages of marble flooring.

a) Softer stone

Marble is a softer stone and is susceptible to scratching, chipping, breaking, etc when compared to any other material like granite, tile, etc. The surface is smooth and light in color and tends to show scratches and defects. Any damage may lead to the replacement of the total area with another piece.

b) Vulnerable to acidic substances

Marble is vulnerable to acidic substances like cleaners, lime, wine coffee, sauces, etc. These can permanently stain and decolor the marble surface.
Hence marble flooring is not preferred for kitchen counters.

c) Slippery surface

Marble gets its looks from polishing. But polishing can make it slippery when it is wet. Hence marble flooring is avoided for wet areas like bathrooms, kitchen, etc.
For overcoming this situation semi-polished or horned marble finishing is to be done. But the horned finish is not as attractive as the mirror finish.

d) Water absorption

Because marble is porous, it’s susceptible to water seeping in and causing damage,stains or discoloration. A penetrating sealer helps keep water from soaking into the flooring.

e) High cost

Marble is one of the high-end stone flooring options. But the durability and life will not be in line with the total cost price of the marble. They may not necessarily last longer than any other flooring options like granite and vitrified tiles. Marble stone is soft and may chip or damage in long run.

f) Weight

Marble stone is very heavy and increases and thereby increases the dead load on a structure. Lifting of marble is difficult when compared to any other flooring material. The building structure has to be strong enough to support the weight of heavy floors.

g) Skilled installation manpower

Marble flooring needs highly skilled and expert manpower for fixing systematically by matching the swirls and grains. Marble stone is a soft material and is prone to cracks. Any mistake in installation may ruin the pattern and also causes huge wastage and financial losses.

h)Maintenance

Acid free mild detergents are to be used for cleaning marble floors. Marble flooring requires annual sealing to restrict the penetration of water and liquids.

Marbles are low heat resistance stone so its floor getting very cold in winter season. So it not suitable for cold regions.

i) Wastage and no availability of matching stone

Marble is a soft stone and tends to crack during loading,transportation and installation and creates a lot of wastage at site.

It is very difficult to change/replace marble flooring once installed. The stone of same colour and design is hard to find after few years. You have to maintain some minimal stock while buying the marble tiles.

Conclusion : Marble is one of the most versatile and luxurious flooring materials that can match any color schemes and themes. The selection of marble as a flooring material depends on the economy, aesthetic requirement, function, and purpose of space.

dams, Hydrauilics

Dams – Site selection, Advantages and Disadvantages

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Site selection for dams is a critical process that ensures the structure’s stability and efficiency. Choosing the right location is essential for minimizing risks and maximizing the dam’s performance. Geology, river flow, and environmental impact are crucial factors. They play a key role in determining the best site selection of a dam. A well-placed dam offers significant advantages, such as water storage and flood control, while improper sites increase the disadvantages of dams, like ecological damage and costly maintenance. Balancing these factors is vital for success.

Dams are obstructions constructed across the water bodies to control the water flow and water levels. Dams serve as a water source for human consumption, irrigation purpose, and power generation. They also help prevent floods when there is a sudden discharge of floodwater. The water that impounds in the dams is also used for recreation purposes and industrial uses. They are mostly made up of rock fill or earthen.

  1. What are dams?
  2. Benefits of dam
  3. Site selection of dams.
  4. Advantages of dams
  5. Disadvantages of Dams
  6. Key Takeaways
  7. Conclusion

What are dams?

The dams are barriers built to restrict and manage the natural flow of rivers, waterways, or streams for human needs. A dam may be a natural one or artificial. They help to confine water and reduces the water rise and flood problems. Dams retain water by forming a reservoir behind the structure. They got an Upstream side and Down stream side. The place where water is collected is called the Upstream side. The water impounded is used as storage and is called Reservoir.

Dams
site selection for dams
Site selection for dams

Also read : Type of Dams – 3 main classification criteria explained

Benefits of dam

The dams provide a range of environmental, economic and social benefits

One of the most important benefits of dams is water storage. The stored water is used for drinking, cleaning, bathing, gardening, irrigation purposes, industrial purposes.

The large dams and reservoirs serve as recreational spots for fishing and boating purposes. Dams play a major role in preventing damages due to floods by collecting and storing excess water during rains and are released as and when required.

The dam is the main source of providing water for irrigation purposes in areas where rain and water are scarce.

Also read : Methods of irrigation – 3 methods full guide

Site selection of dams.

The dam is a massive and strategic structure and needs a perfect site selection before proceeding with construction.Site selection of dams involves assessing factors like geology, river flow, and environmental impact. These factors ensure structural stability and reduce ecological disruption. The right site selection for dams minimizes risks such as flooding and maintenance issues. Soil type, valley shape, and climate also play a key role in site viability.

  • Topography -Making maximum use of the available volume of water is the main objective of a dam. The slope of the area, groundwater table, contour, weather condition, etc is other factors for dam site selection. The bed level at the dam site should preferably be higher than that of the river basin. This is for reducing the dam height and facilitating the drainage of water.
  • Foundation – The foundation should bear the whole weight and pressure of the dam. It should be permeable, thick, and should have adequate strength.
  • Economic criteria – This includes the construction and maintenance cost of the dam. The land value, cost of construction materials and construction time, etc. to be taken into account while selecting a dam site. Quality construction materials required for dam construction have to be available near the proposed location. Always opt for a small length dam with maximum water holding capacity for economising the project. 
  • Height of Dam – The height of the dam should be economical, and should store the maximum amount of water.
  • Earthquake zone – The dam site should not be an earthquake zone. It may cause a collapse of the dam and losses. 
  • Material availability – Materials like rock, aggregate, soil, filler, etc. should be available near the site.
  • Climate condition – The climate of the site should be bearable, possibilities of landslides should not occur.
  • Spillway site: A suitable location for the spillway should be available in the nearby vicinity of the dam. 
  • The dam site should be easily accessible and economically connected to nearby areas. Area required for establishments and labour camps of construction group shall be available nearby in a safe zone.
  • Environmental issues should be taken into consideration while selecting the dam site.
Dam with sluice gate
Dam site selection

Advantages of dams

  • Water storage : Dams are one of the major sources of water for domestic uses. These uses include cooking, cleaning, bathing, washing, drinking water, and gardening. They also provide water for agricultural and industrial purposes. The water is supplied through the canal or with the help of a pipe system from the dam.
  • Irrigation – The water from the dams is diverted through canals. This water reaches fields where the water level is low. It is used for irrigation purposes.
  • Hydroelectric power – The water stored in the dam is passed through turbines for hydroelectric power generation.
  • Flood prevention – The water level of river, streams, etc are maintained by constructing dams across it. This prevents the loss and damages from unexpected floods. 
  • Recreation – The water stored in the dam is used for fishing, boating, and other recreational activities.
  • Debris control – Dam also provides the retention of hazardous material and protects the environment.

Disadvantages of Dams

  • Groundwater table – Stagnation of water in the dams alters the groundwater table.
  • Ecosystem – The dams prevent the fish migration and help in the breeding of mosquito which affects the ecosystem.
  • Water temperature – The aquatic temperature is varied by the dams, which causes a serious problem for aquatic lives.
  • Greenhouse effect – The reservoirs emit greenhouse gases which leads to global warming.
  • Rehabilitation – The discharge of water from the river affects the peoples living in the downstream area.

Key Takeaways

  • Importance of Site Selection: Effective dam construction relies on careful site selection, considering hydrological and geological factors.
  • Advantages of Dams:
    • Provide water storage for irrigation and drinking.
    • Offer flood control and management.
    • Generate hydroelectric power, contributing to energy supply.
  • Disadvantages of Dams:
    • Can lead to environmental degradation and loss of biodiversity.
    • May displace local communities and affect livelihoods.
    • Alter aquatic ecosystems and sediment transport.
  • Mitigation Strategies: Comprehensive environmental assessments and proper planning can help address negative impacts.
  • Stakeholder Engagement: Involving local communities in the decision-making process enhances public acceptance and addresses concerns.
  • Balanced Decision-Making: Understanding both advantages and disadvantages of dams is vital for informed policy and engineering choices.
  • Sustainable Practices: Prioritizing sustainability in dam projects ensures long-term benefits for both society and the environment.

Conclusion

The process of dams site selection requires careful consideration of various factors. It involves balancing the advantages of water management and energy generation. These must be weighed against the disadvantages related to environmental and social impacts. By prioritizing sustainable practices and involving communities in decision-making, the negative consequences of dams can be minimized. Policymakers and engineers must adopt an integrated approach to site selection for dams. This approach ensures the benefits provided align with ecological preservation. It also supports social equity. A well-informed strategy will help develop dams that positively impact society. It will also protect natural resources for future generations.

bridges, TRANSPORTATION ENGINEERING

Component of a bridge|Bridge components-Types, functions

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Component of a bridge/ bridge components plays a very important role in maintaining the stability and functional requirements of the bridge structure. Each bridge component has its functions. The bridge component types and functions vary as per the site conditions, design requirements, and functional requirements. This article is about a total overview of the components of bridge/bridge components.

A bridge is a structure built over physical obstacles such as water bodies like rivers, lakes, canals, etc, and valleys, roads, etc with minimal obstructing to the area below. During ancient times bridges are made by falling of trees, providing stepping stones, and by tying a rope from the trees. Bridges are the most important components of a highway, railway, and urban roads. Brides play an important role in the socio-economic, politics, culture, defence, etc of a region and a country.

  1. Component of a bridge / Bridge components
    1. Bridge components – Substructure
      1. Bridge components – Abutments
        1. Types of Abutments
      2. Wing walls and return walls
      3. Piers
      4. Foundation
    2. Component of a bridge – Super structure or decking components
      1. Bridge bearings
      2. Decking components
  2. Key Takeaways
  3. Conclusion
  4. Latest posts

Also read : Components of a road – Elements and their function

Also read : Components of a railway track – Types and functions

Component of a bridge / Bridge components

The components of the bridges are divided broadly into .

Diagram illustrating the components of a bridge, highlighting substructure and superstructure elements.
Illustration depicting the components of a bridge, highlighting substructure and superstructure elements.

a) Sub- structure

c) Super structure or decking component

Components of a bridge below the bearing constitute substructure and components above the bearings constitute superstructure or decking components.

You tube video – Components of a Bridge

VIDEO SHOWING BRIDGE COMPONENTS/COMPONENT OF A BRIDGE

Bridge components – Substructure

The main function of the substructure is to support the superstructure components and transfer the loads to safe strata. The major substructure components of a bridge are as follows.

a) Abutments

b) Wing walls and return walls

c) Piers

d) Pier cap

e) Foundation

Diagram illustrating the components of a bridge, including the approach slab, parapet, bridge deck slab, span girders, abutment, pier cap, bearing, pier, and pile cap.
Diagram illustrating the components of a bridge, including the approach slab, span girders, abutment, pier, and bearing.
Components of a bridge

Bridge components – Abutments

Abutments functions as vertical supports to the superstructure components at the bridge end. They are the endpoints of a bridge and acts as an approach for the roadway. Abutments retain the roadway backfill and base materials and act as lateral support to the embankments approach. Because of these properties, the abutments are designed as retaining structures.

A single span bridges got two abutments which serves as a vertical support and lateral support. Abutments also resist lateral movement of earth fill of the road approaches.

Illustration of abutment components showing vertical loads, deck beam, beam seat, and back wall for retaining backfill.
Illustration of the components of an abutment, highlighting its role in supporting deck beams and resisting lateral loads.
components of abutment

Abutment are of various types depending on the design requirements and load considerations.

Cross section diagram of a bridge abutment showing components like aggregate fill, compacted subgrade, back fill, approach slab, expansion joint, and deck slab.
Cross section illustration of a bridge abutment showing its structural components and layering.
Cross section of abutment
Types of Abutments
  • Closed Abutment
  • Stub or Perched Abutment 
  • Pedestal or Spill-through Abutment
  • Integral End Bents
  • Mechanically Stabilized Abutment

Wing walls and return walls

Wing walls are located near to the abutments as an extension of abutments or as independent structures. They act as a retaining wall to resist the earth in the approach areas. Wing walls may be placed right-angled to the approach way or splayed as shown in the figure.

Piers

Piers are intermediate vertical supports provided between bridge spans. The main function of a pier is to transfer the loads coming on the superstructure to the foundations. Pier got pier caps to provide sufficient bearing areas for the transfer of superstructure loads.

Piers are basically compression members and are designed for vertical loads but in high seismic areas they are designed for lateral loads also.

Underneath view of a bridge showing its structural components, including piers and beams, over a water body.
View of bridge piers supporting the superstructure above water, showcasing essential components of bridge stability.
Piers

Foundation

Foundations are constructed to transfer loads coming on the superstructure and substructure to a larger area and hard strata. The foundations may be an open foundation or pile foundation or some other foundation type depends upon nature or soil strata and design considerations. The foundation has to be provided at sufficient depth to ensure protection and chances of failure against the scouring and undermining process.

Also read : Foundation types – Shallow and deep foundations

Also read : Pile foundations – Types and advantages

Component of a bridge – Super structure or decking components

The superstructure constitutes deck slabs, deck beams/girders, trusses, cables, arches, handrails, parapet, etc. The superstructure components depend on the type of bridge-like concrete, composite, steel, etc. The following are the basic superstructure components.

a) Bearings

b) Bridge deck

Diagram illustrating the components of a bridge superstructure, including deck slab, deck beam, bridge bearings, and parapet.
Diagram illustrating the superstructure components of a bridge, including deck slab, deck beam, bridge bearings, and parapet.
SUPERSTRUCTURE COMPONENTS

Bridge bearings

Bridge bearings are components of the bridge that provides a resting surface between the bridge pier and the bridge deck. The main function of the bearing is to control movements and reduces the stresses involved.

A bridge bearing carries the loads or movement in both vertical and horizontal directions from the bridge superstructure and transfers those loads to the bridge pier and abutments. The loads can be live load and dead load in vertical directions, or wind load, earthquake load, etc., in horizontal directions.

Close-up view of a bridge bearing system, showing the connection between the bridge deck and the support structure below.
Close-up view of a bridge bearing, showcasing its structural connection between the bridge deck and pier.
Bridge bearing

Decking components

Decking is the surface over which the traffic like road or rail passes. The decks are supported on beams, girders (prestressed or post-tensioned ) viaducts, prefabricated segments, steel girders or hanged through cables. The whole decking components are supported by pier which transfer the loads to reliable soil strata.

The deck beams shall be conventional rectangular type or of I – GIRDERS (Concrete or steel)

Construction of a bridge showing concrete beams supported by scaffolding and equipment.
Construction of a bridge superstructure featuring concrete beams supported by piers.
Types of Deck support beams

The surface of the deck may be of the concrete or bituminous for movement of traffic.

There are a lot of miscellaneous components like strip seal expansion joints which separates the deck spans, Hand rails are provided on the deck side as a barrier and protection.

Key Takeaways

  1. Bridge Importance: Bridges connect regions over obstacles like water bodies and valleys.
  2. Component Categories: Divided into substructures and superstructures.
  3. Substructure Components: Includes abutments, wing walls, piers, pier caps, and foundations.
  4. Abutments: Serve as vertical and lateral support, retaining roadway backfill and providing bridge endpoints.
  5. Wing Walls: Act as retaining walls near abutments, resisting earth in approach areas.
  6. Piers: Provide intermediate vertical support between spans, transferring loads to foundations.
  7. Foundations: Ensure stability against scouring and undermining, transferring loads to the ground.
  8. Superstructure Components: Comprise deck slabs, beams, trusses, cables, arches, handrails, and parapets.
  9. Bridge Bearings: Control movements and reduce stresses, transferring loads to piers and abutments.
  10. Decking: Forms the surface for traffic, supported by beams and girders, ensuring efficient load distribution.
  11. Miscellaneous Components: Include expansion joints and handrails for protection and separation of deck spans.

Conclusion

Understanding bridge components is crucial for maintaining stability and functionality. The substructure, including abutments, piers, and foundations, supports and distributes loads to the ground, while the superstructure, comprising decking, beams, and bearings, facilitates traffic flow and load transfer. Abutments provide vertical and lateral support, retaining backfill and serving as endpoints. Piers act as intermediate supports, and foundations ensure stability against environmental factors. The superstructure supports traffic with decks and beams, transferring loads through bearings to the substructure. These components work together to create safe, efficient, and durable bridges, highlighting the importance of comprehensive design and construction in bridge engineering.

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