A final semester thesis done to study the feasibility of a RoR Hydropower in Tila Nadi River, Jumla with the secondary objective of providing water supply to people of Nagma Bazar, Kalikot.
The report details the proposed 10 MW Sagana-III run-of-river hydroelectric project on the Sagana River in Kenya. Key aspects include a diversion weir at 1274m elevation, 4.8 km water conductor system consisting of tunnels and channels, a forebay, 175m penstock bifurcating to two 1.9m pipes, and a 1210m elevation powerhouse with two 5MW turbines. The project will utilize a 58.46m head and 21.26 cumecs flow to generate an estimated 54 million kWh annually, connecting to the grid via a 7km transmission line. Financial analysis shows an equity IRR of 16.12% and average DSCR of 1.54x,
TERZAGHI’S BEARING CAPACITY THEORY
DERIVATION OF EQUATION TERZAGHI’S BEARING CAPACITY THEORY
TERZAGHI’S BEARING CAPACITY FACTORS
Download vedio link
https://youtu.be/imy61hU0_yo
The document provides details about the survey camp conducted by Nepal Engineering College from June 10-19, 2078. It summarizes the various surveying tasks conducted during the camp, including topographic surveying of the area surrounding Hotel Heaven Hill. The objectives of the survey camp were to provide practical surveying experience and produce a topographic map, contour map, and surveys of a road alignment and bridge site. Surveying methods like traversing, leveling, detailing, and contouring were used to collect field data and create maps within specified accuracy standards.
The document discusses various techniques for soil stabilization used in road construction. It defines soil stabilization as treating soil to maintain or improve its performance. Key techniques include mechanical stabilization by blending soils, and chemical stabilization by adding lime, cement or other chemicals. Mechanical methods improve strength through compaction and grading, while chemical additives cause reactions improving properties like strength and durability over time. The document provides details on various soil stabilization mixtures and their applications in road construction.
The document discusses activities, projects, and bar charts for project scheduling. An activity has a defined start and end time and uses resources. A project is a set of activities with defined objectives, completion date, and budget. A bar chart is a common project scheduling tool that displays activities as horizontal bars placed sequentially according to duration and dependencies. It can identify critical paths where delays could impact the overall project schedule.
The document summarizes the construction process of columns for a seven storied residential building. It describes the process of forming kickers, placing reinforcement bars, shuttering, casting, and curing concrete columns. It provides details on the types and sizes of columns constructed, reinforcement details, and estimates of required construction materials. Laboratory and field tests were conducted to ensure quality of materials and construction methods.
This document discusses collapsible soils and how to assess their collapse potential and calculate expected settlements. There are two types of soils that exhibit volume changes with water content changes - collapsible soils that decrease in volume (collapse) when wetted and expansive soils that increase in volume (swell) when wetted. The document outlines methods to determine collapse potential from consolidation tests and calculate collapse settlements using a double oedometer test procedure. It provides examples of applying these methods to calculate collapse settlements for normally consolidated and overconsolidated soil conditions. Foundation design in collapsible soils requires special consideration due to the risk of large wetting-induced settlements.
The report details the proposed 10 MW Sagana-III run-of-river hydroelectric project on the Sagana River in Kenya. Key aspects include a diversion weir at 1274m elevation, 4.8 km water conductor system consisting of tunnels and channels, a forebay, 175m penstock bifurcating to two 1.9m pipes, and a 1210m elevation powerhouse with two 5MW turbines. The project will utilize a 58.46m head and 21.26 cumecs flow to generate an estimated 54 million kWh annually, connecting to the grid via a 7km transmission line. Financial analysis shows an equity IRR of 16.12% and average DSCR of 1.54x,
TERZAGHI’S BEARING CAPACITY THEORY
DERIVATION OF EQUATION TERZAGHI’S BEARING CAPACITY THEORY
TERZAGHI’S BEARING CAPACITY FACTORS
Download vedio link
https://youtu.be/imy61hU0_yo
The document provides details about the survey camp conducted by Nepal Engineering College from June 10-19, 2078. It summarizes the various surveying tasks conducted during the camp, including topographic surveying of the area surrounding Hotel Heaven Hill. The objectives of the survey camp were to provide practical surveying experience and produce a topographic map, contour map, and surveys of a road alignment and bridge site. Surveying methods like traversing, leveling, detailing, and contouring were used to collect field data and create maps within specified accuracy standards.
The document discusses various techniques for soil stabilization used in road construction. It defines soil stabilization as treating soil to maintain or improve its performance. Key techniques include mechanical stabilization by blending soils, and chemical stabilization by adding lime, cement or other chemicals. Mechanical methods improve strength through compaction and grading, while chemical additives cause reactions improving properties like strength and durability over time. The document provides details on various soil stabilization mixtures and their applications in road construction.
The document discusses activities, projects, and bar charts for project scheduling. An activity has a defined start and end time and uses resources. A project is a set of activities with defined objectives, completion date, and budget. A bar chart is a common project scheduling tool that displays activities as horizontal bars placed sequentially according to duration and dependencies. It can identify critical paths where delays could impact the overall project schedule.
The document summarizes the construction process of columns for a seven storied residential building. It describes the process of forming kickers, placing reinforcement bars, shuttering, casting, and curing concrete columns. It provides details on the types and sizes of columns constructed, reinforcement details, and estimates of required construction materials. Laboratory and field tests were conducted to ensure quality of materials and construction methods.
This document discusses collapsible soils and how to assess their collapse potential and calculate expected settlements. There are two types of soils that exhibit volume changes with water content changes - collapsible soils that decrease in volume (collapse) when wetted and expansive soils that increase in volume (swell) when wetted. The document outlines methods to determine collapse potential from consolidation tests and calculate collapse settlements using a double oedometer test procedure. It provides examples of applying these methods to calculate collapse settlements for normally consolidated and overconsolidated soil conditions. Foundation design in collapsible soils requires special consideration due to the risk of large wetting-induced settlements.
The document provides information about the course CE8701 Estimation, Costing and Valuation Engineering. It discusses the objectives of the course which is to provide knowledge in estimation, tender practices, contract procedures and valuation. It outlines the 5 units that will be covered: quantity estimation, rate analysis and costing, specifications, reports and tenders, contracts, and valuation. It also provides examples of how to prepare rough cost estimates using the plinth area and unit base methods and how to take out quantities for preparing a detailed estimate using the centre line and long wall and short wall methods.
The document discusses computing runoff depth using infiltration capacity curves. It provides the following information:
1) An infiltration capacity curve plots infiltration capacity against time and can be superimposed on a rainfall graph to determine infiltration (dotted area) and runoff (hatched area).
2) Horton's equation is used to model the time evolution of infiltration capacity assuming unlimited water supply at the soil surface.
3) An example computation is shown applying Horton's equation and comparing infiltration capacity to precipitation intensity to determine actual infiltration and runoff rates over time.
Reconnaissance for Hydrographic Surveying ProjectNzar Braim
Reconnaissance for Hydrographic
Surveying Project
This report talks about how the reconnaissance will be and it is effectively important the place that we survey and observation so the surveyor should prepare himself or herself for the project visiting site and site survey and planning and so on.
Observer visiting the site many times daily to see what is the situation and the condition and booking his or her notes recording them such as is the site ready to start the observation? Or is the site has safety to start? I mean replace safety conditions and also must have collected all this information and choose which instrument this site or this project and many other conditions should be considered after all above that I have mentioned he or she decides to start and beginning Project and surveying or not. This is the idea or this the outline recognizes.
Class 1 Moisture Content - Specific Gravity ( Geotechnical Engineering )Hossam Shafiq I
This document provides an introduction to a geotechnical engineering laboratory course at Texas Tech University. It includes information about the course syllabus, schedule, report format, and the objectives and procedures for the first lab which involves determining the moisture content, unit weight, and specific gravity of a soil sample. The significance of understanding soil properties for civil engineers is discussed. Key relationships between the weight and volume of the solid, water, and air phases in a soil sample are also explained.
Precipitation occurs when atmospheric moisture condenses and falls to the earth's surface. The main forms of precipitation are rain, snow, hail, drizzle and dew. Precipitation is measured using rain gauges and satellite imagery. There are various types of precipitation depending on what causes the air to lift and cool, such as convection, orographic lifting, and cyclonic storms. Data from rain gauges needs to be quality controlled to ensure accuracy by checking for consistency using methods like double mass curves and adjusting records when inconsistencies are found.
1. The document discusses slope stability analysis using the Swedish slip circle method for analyzing finite slopes made of cohesive soils.
2. It describes the assumptions of the method and calculates the factors of safety for circular failure surfaces with and without tension cracks.
3. The document also covers other methods like the ordinary method of slices for c-f soils and discusses locating the critical slip circle using empirical relationships.
(1) The sand replacement method is used to determine the field density of soil containing coarse particles like gravel or stones, where the core cutter method is not suitable. (2) The method involves excavating a hole in the compacted soil and measuring the volume of the hole by filling it with calibrated sand. (3) The density of the in-situ soil is then calculated as the weight of the excavated soil divided by the volume of the hole determined through filling it with the calibrated sand.
Shortcomings of bar charts include lack of detail, inability to show activity interrelationships and progress. Milestone charts address these by breaking activities into sections and using milestones to mark portions of activities. Network diagrams represent projects as activities (arrows) and events (circles) connected logically and sequentially. Critical activities lie on the longest path through the network. Slack/float is the amount of time an activity can be delayed without delaying subsequent activities or the project.
A group of 16 square piles extends 12 m into stiff clay soil, underlain by rock at 24 m depth. Pile dimensions are 0.3 m x 0.3 m. Undrained shear strength of clay increases linearly from 50 kPa at surface to 150 kPa at rock. Factor of safety for group capacity is 2.5. Determine group capacity and individual pile capacity.
The group capacity is calculated to be 1600 kN. The individual pile capacity is determined to be 100 kN. The factor of safety of 2.5 is then applied to determine the safe load capacity.
The document provides details on calculating earthwork for a road construction project in Tank Road, D.I. Khan, Pakistan. It describes measuring cross-sectional areas along the road to determine cut and fill volumes needed. Cross sections were taken every 25 meters using a total station. The cut and fill areas were calculated in AutoCAD and exported to Excel to determine total cubic meters of earthwork. The results tables show the cut and fill volumes calculated for 40 cross sections along 1 kilometer of roadway.
*Introduction
*Controls For Setting Out
*Horizontal control
*Vertical control
*SETTING OUT A BUILDING
*The equipment required for the job
*Method(1):-By using a Circumscribing Rectangle
*Method(2):- By using centre-line-rectangle
* Setting out of culverts
*SETTING OUT A TUNNEL
The document provides an overview of a training course on FIDIC forms of contracts. It discusses the history and objectives of FIDIC and their various standard form contracts, including the Red, Yellow, Silver, and Green books. It also outlines some of the key features and clauses of the FIDIC contracts, such as the roles of the engineer and communication procedures. The training course will cover topics like risk management, procurement strategies, and dispute resolution in FIDIC contracts over the course of several lectures.
SOIL COMPACTION AND ITS EFFECT ON PROPERTIESGeorgeThampy
soil compaction occurs when soil particles are pressed together so that reduction in pore space between them.soil compaction increases the shear strength of the soil.And soil compaction is much effective in earth dams.
The substance system is a form of tangential measurement where the measured base is held horizontally using a specially made substance bar supported on a tripod with precisely spaced targets. The central target is placed midway between the end targets for measuring traverse angles and sighting with the auxiliary base method. The key formula for the substance system calculates the horizontal distance from the half angle of sighting and the known length of the substance bar, and additional formulas are provided to calculate vertical components and reduced staff heights.
Numerical problem bearing capacity terzaghi , group pile capacity (usefulsear...Make Mannan
A 1m wide strip footing is located 0.8m below ground in a c-φ soil. The soil properties are given. Using Terzaghi's analysis with a factor of safety of 3, the safe bearing capacity is calculated to be 112.1 kN/m^2.
A 2m x 3m rectangular footing at a depth of 1.5m in a different c-φ soil is considered. Using Terzaghi's analysis, the safe bearing capacities are calculated to be 471.7 kN/m^2 based on net ultimate capacity and 453.7 kN/m^2 based on ultimate capacity, both with a factor of safety of 3.
1. The document discusses different types of foundations, including shallow foundations like spread footings and deep foundations like piles.
2. It covers bearing capacity theories proposed by Rankine, Terzaghi, Meyerhof, and Hansen. Terzaghi's theory is the most commonly used approach.
3. Key factors that influence bearing capacity are discussed, along with effects of the groundwater table. Allowable bearing capacity is defined using a factor of safety.
surveying Engineering
Fly Levelling
Fly leveling: -Fly leveling is just like differential leveling carried
out to check the accuracy of leveling work. It is a very approximate
form of leveling in which sights are taken as large as possible. in this
method, a line of levels is run to determine approximately reduced
levels of the points carried out with more rapidly and less precision
The aim of fly Levelling: The main purpose of this type of leveling is
to check the values of the reduced levels of the bench marks already
fixed. In this method only back sight and foresight are taken. There is no need of intermediate sights. However great care has to be taken for selecting the change points (Turning Points) and for taking reading on the change points because the accuracy of leveling depends upon these
-Create Bench Marks (BM).
Bench Marks
Bench Mark is a point of known elevation, there are three Type of Bench Marks
1-Perment Bench Mark.
2-Orbitrary Bench Mark .
3-Temporary Bench Mark .
-Leveling Process Calculation.
1. Height of collimation method
2. Rise and Fall method
How do we find horizontal distance using levelling Machine.
Fly Levelling Close loop survey.
Fly and Differential leveling Using (Rise & fall) and (HI)methods.
*Checks for Errors
-Misclosure
Allowable closing error
Where:
D =Distance in km
E = Misclosure error in (mm).
C = 30 for fixed levelling process in rough ground.
C = 15 for normal leveling in flat area (Good work)
Fly Levelling example
Computation of Elevations for an open loop survey H.I method
Computation of Elevations
Differential Leveling
Computation of Elevations
-Correction For Errors in Leveling
1. Errors Due to the line of sight being not horizontal
2. Error Due to Curvature and refraction.
Errors in differential leveling: -
1) Non adjustment of the instrument: -
a) Adjustment of cross-wire ring
b) Adjustment of the bubble tube
c) Adjustment of line of sight
2-Errors in levelling
• Collimation line
• Parallax
• Change point instability
• Instrument instability
• Benchmark instability
• Staff reading errors , • Staff verticality • Level Instrument shading • Temperature on staff • Booking errors) • Earth curvature • Refraction • The Bubble not center.
3-Constant error (instrumental error):
A. Non vertically of the staff.
B. Collimation error in the instrument.
C. Staff gradation error.
4- Random error (natural error):
A. Effect of wind and temperature.
B. Soft and hard ground.
C. Change points. CP
D. Human deficiencies and neglect
Prepared by:
Asst. Prof. Salar K.Hussein
Mr. Kamal Y.Abdullah
Asst.Lecturer. Dilveen H. Omar
Erbil Polytechnic University
Technical Engineering College
Civil Engineering Department
This document summarizes a seminar presentation on developing a new drought index called the Standardized Wetness Index (SWI) that considers the joint effects of climate and land surface change. The presentation reviews existing drought indices and their limitations in accounting for these effects. It then describes calculating the SWI using a residual water energy ratio fitted to a probability distribution with a parameter (n) representing climate-land surface interactions. The SWI is validated using two catchments experiencing land use changes, showing n correlates with restoration efforts and the SWI detects reported droughts. The SWI provides a way to assess dryness/wetness from both climate change alone and combined climate-land surface effects.
Class notes of Geotechnical Engineering course I used to teach at UET Lahore. Feel free to download the slide show.
Anyone looking to modify these files and use them for their own teaching purposes can contact me directly to get hold of editable version.
The document discusses canal design and presents several examples of calculations using the HCANAL software. It begins with introductions to canals and the HCANAL software. Then, it covers theoretical concepts of canal design including design of rectangular and trapezoidal canal sections. Finally, it presents 7 sample problems demonstrating calculations for discharge, velocity, dimensions and other hydraulic elements using the software. The problems cover a range of canal shapes, materials, slopes and flow conditions.
This project report summarizes the analysis and design of an underground drainage system for the hostel areas of SRM University in Kattankulathur, India. The report outlines the objectives, necessity, scope and methodology of the project. It involves surveying the existing drainage system, analyzing wastewater and stormwater flows, selecting appropriate pipe materials, and designing the pipe network layout, trenches, manholes and cost estimate. The aim is to provide a systematic underground sewerage system to replace the existing open channel drainage and improve sanitation, flooding prevention and environmental protection on campus.
The document provides information about the course CE8701 Estimation, Costing and Valuation Engineering. It discusses the objectives of the course which is to provide knowledge in estimation, tender practices, contract procedures and valuation. It outlines the 5 units that will be covered: quantity estimation, rate analysis and costing, specifications, reports and tenders, contracts, and valuation. It also provides examples of how to prepare rough cost estimates using the plinth area and unit base methods and how to take out quantities for preparing a detailed estimate using the centre line and long wall and short wall methods.
The document discusses computing runoff depth using infiltration capacity curves. It provides the following information:
1) An infiltration capacity curve plots infiltration capacity against time and can be superimposed on a rainfall graph to determine infiltration (dotted area) and runoff (hatched area).
2) Horton's equation is used to model the time evolution of infiltration capacity assuming unlimited water supply at the soil surface.
3) An example computation is shown applying Horton's equation and comparing infiltration capacity to precipitation intensity to determine actual infiltration and runoff rates over time.
Reconnaissance for Hydrographic Surveying ProjectNzar Braim
Reconnaissance for Hydrographic
Surveying Project
This report talks about how the reconnaissance will be and it is effectively important the place that we survey and observation so the surveyor should prepare himself or herself for the project visiting site and site survey and planning and so on.
Observer visiting the site many times daily to see what is the situation and the condition and booking his or her notes recording them such as is the site ready to start the observation? Or is the site has safety to start? I mean replace safety conditions and also must have collected all this information and choose which instrument this site or this project and many other conditions should be considered after all above that I have mentioned he or she decides to start and beginning Project and surveying or not. This is the idea or this the outline recognizes.
Class 1 Moisture Content - Specific Gravity ( Geotechnical Engineering )Hossam Shafiq I
This document provides an introduction to a geotechnical engineering laboratory course at Texas Tech University. It includes information about the course syllabus, schedule, report format, and the objectives and procedures for the first lab which involves determining the moisture content, unit weight, and specific gravity of a soil sample. The significance of understanding soil properties for civil engineers is discussed. Key relationships between the weight and volume of the solid, water, and air phases in a soil sample are also explained.
Precipitation occurs when atmospheric moisture condenses and falls to the earth's surface. The main forms of precipitation are rain, snow, hail, drizzle and dew. Precipitation is measured using rain gauges and satellite imagery. There are various types of precipitation depending on what causes the air to lift and cool, such as convection, orographic lifting, and cyclonic storms. Data from rain gauges needs to be quality controlled to ensure accuracy by checking for consistency using methods like double mass curves and adjusting records when inconsistencies are found.
1. The document discusses slope stability analysis using the Swedish slip circle method for analyzing finite slopes made of cohesive soils.
2. It describes the assumptions of the method and calculates the factors of safety for circular failure surfaces with and without tension cracks.
3. The document also covers other methods like the ordinary method of slices for c-f soils and discusses locating the critical slip circle using empirical relationships.
(1) The sand replacement method is used to determine the field density of soil containing coarse particles like gravel or stones, where the core cutter method is not suitable. (2) The method involves excavating a hole in the compacted soil and measuring the volume of the hole by filling it with calibrated sand. (3) The density of the in-situ soil is then calculated as the weight of the excavated soil divided by the volume of the hole determined through filling it with the calibrated sand.
Shortcomings of bar charts include lack of detail, inability to show activity interrelationships and progress. Milestone charts address these by breaking activities into sections and using milestones to mark portions of activities. Network diagrams represent projects as activities (arrows) and events (circles) connected logically and sequentially. Critical activities lie on the longest path through the network. Slack/float is the amount of time an activity can be delayed without delaying subsequent activities or the project.
A group of 16 square piles extends 12 m into stiff clay soil, underlain by rock at 24 m depth. Pile dimensions are 0.3 m x 0.3 m. Undrained shear strength of clay increases linearly from 50 kPa at surface to 150 kPa at rock. Factor of safety for group capacity is 2.5. Determine group capacity and individual pile capacity.
The group capacity is calculated to be 1600 kN. The individual pile capacity is determined to be 100 kN. The factor of safety of 2.5 is then applied to determine the safe load capacity.
The document provides details on calculating earthwork for a road construction project in Tank Road, D.I. Khan, Pakistan. It describes measuring cross-sectional areas along the road to determine cut and fill volumes needed. Cross sections were taken every 25 meters using a total station. The cut and fill areas were calculated in AutoCAD and exported to Excel to determine total cubic meters of earthwork. The results tables show the cut and fill volumes calculated for 40 cross sections along 1 kilometer of roadway.
*Introduction
*Controls For Setting Out
*Horizontal control
*Vertical control
*SETTING OUT A BUILDING
*The equipment required for the job
*Method(1):-By using a Circumscribing Rectangle
*Method(2):- By using centre-line-rectangle
* Setting out of culverts
*SETTING OUT A TUNNEL
The document provides an overview of a training course on FIDIC forms of contracts. It discusses the history and objectives of FIDIC and their various standard form contracts, including the Red, Yellow, Silver, and Green books. It also outlines some of the key features and clauses of the FIDIC contracts, such as the roles of the engineer and communication procedures. The training course will cover topics like risk management, procurement strategies, and dispute resolution in FIDIC contracts over the course of several lectures.
SOIL COMPACTION AND ITS EFFECT ON PROPERTIESGeorgeThampy
soil compaction occurs when soil particles are pressed together so that reduction in pore space between them.soil compaction increases the shear strength of the soil.And soil compaction is much effective in earth dams.
The substance system is a form of tangential measurement where the measured base is held horizontally using a specially made substance bar supported on a tripod with precisely spaced targets. The central target is placed midway between the end targets for measuring traverse angles and sighting with the auxiliary base method. The key formula for the substance system calculates the horizontal distance from the half angle of sighting and the known length of the substance bar, and additional formulas are provided to calculate vertical components and reduced staff heights.
Numerical problem bearing capacity terzaghi , group pile capacity (usefulsear...Make Mannan
A 1m wide strip footing is located 0.8m below ground in a c-φ soil. The soil properties are given. Using Terzaghi's analysis with a factor of safety of 3, the safe bearing capacity is calculated to be 112.1 kN/m^2.
A 2m x 3m rectangular footing at a depth of 1.5m in a different c-φ soil is considered. Using Terzaghi's analysis, the safe bearing capacities are calculated to be 471.7 kN/m^2 based on net ultimate capacity and 453.7 kN/m^2 based on ultimate capacity, both with a factor of safety of 3.
1. The document discusses different types of foundations, including shallow foundations like spread footings and deep foundations like piles.
2. It covers bearing capacity theories proposed by Rankine, Terzaghi, Meyerhof, and Hansen. Terzaghi's theory is the most commonly used approach.
3. Key factors that influence bearing capacity are discussed, along with effects of the groundwater table. Allowable bearing capacity is defined using a factor of safety.
surveying Engineering
Fly Levelling
Fly leveling: -Fly leveling is just like differential leveling carried
out to check the accuracy of leveling work. It is a very approximate
form of leveling in which sights are taken as large as possible. in this
method, a line of levels is run to determine approximately reduced
levels of the points carried out with more rapidly and less precision
The aim of fly Levelling: The main purpose of this type of leveling is
to check the values of the reduced levels of the bench marks already
fixed. In this method only back sight and foresight are taken. There is no need of intermediate sights. However great care has to be taken for selecting the change points (Turning Points) and for taking reading on the change points because the accuracy of leveling depends upon these
-Create Bench Marks (BM).
Bench Marks
Bench Mark is a point of known elevation, there are three Type of Bench Marks
1-Perment Bench Mark.
2-Orbitrary Bench Mark .
3-Temporary Bench Mark .
-Leveling Process Calculation.
1. Height of collimation method
2. Rise and Fall method
How do we find horizontal distance using levelling Machine.
Fly Levelling Close loop survey.
Fly and Differential leveling Using (Rise & fall) and (HI)methods.
*Checks for Errors
-Misclosure
Allowable closing error
Where:
D =Distance in km
E = Misclosure error in (mm).
C = 30 for fixed levelling process in rough ground.
C = 15 for normal leveling in flat area (Good work)
Fly Levelling example
Computation of Elevations for an open loop survey H.I method
Computation of Elevations
Differential Leveling
Computation of Elevations
-Correction For Errors in Leveling
1. Errors Due to the line of sight being not horizontal
2. Error Due to Curvature and refraction.
Errors in differential leveling: -
1) Non adjustment of the instrument: -
a) Adjustment of cross-wire ring
b) Adjustment of the bubble tube
c) Adjustment of line of sight
2-Errors in levelling
• Collimation line
• Parallax
• Change point instability
• Instrument instability
• Benchmark instability
• Staff reading errors , • Staff verticality • Level Instrument shading • Temperature on staff • Booking errors) • Earth curvature • Refraction • The Bubble not center.
3-Constant error (instrumental error):
A. Non vertically of the staff.
B. Collimation error in the instrument.
C. Staff gradation error.
4- Random error (natural error):
A. Effect of wind and temperature.
B. Soft and hard ground.
C. Change points. CP
D. Human deficiencies and neglect
Prepared by:
Asst. Prof. Salar K.Hussein
Mr. Kamal Y.Abdullah
Asst.Lecturer. Dilveen H. Omar
Erbil Polytechnic University
Technical Engineering College
Civil Engineering Department
This document summarizes a seminar presentation on developing a new drought index called the Standardized Wetness Index (SWI) that considers the joint effects of climate and land surface change. The presentation reviews existing drought indices and their limitations in accounting for these effects. It then describes calculating the SWI using a residual water energy ratio fitted to a probability distribution with a parameter (n) representing climate-land surface interactions. The SWI is validated using two catchments experiencing land use changes, showing n correlates with restoration efforts and the SWI detects reported droughts. The SWI provides a way to assess dryness/wetness from both climate change alone and combined climate-land surface effects.
Class notes of Geotechnical Engineering course I used to teach at UET Lahore. Feel free to download the slide show.
Anyone looking to modify these files and use them for their own teaching purposes can contact me directly to get hold of editable version.
The document discusses canal design and presents several examples of calculations using the HCANAL software. It begins with introductions to canals and the HCANAL software. Then, it covers theoretical concepts of canal design including design of rectangular and trapezoidal canal sections. Finally, it presents 7 sample problems demonstrating calculations for discharge, velocity, dimensions and other hydraulic elements using the software. The problems cover a range of canal shapes, materials, slopes and flow conditions.
This project report summarizes the analysis and design of an underground drainage system for the hostel areas of SRM University in Kattankulathur, India. The report outlines the objectives, necessity, scope and methodology of the project. It involves surveying the existing drainage system, analyzing wastewater and stormwater flows, selecting appropriate pipe materials, and designing the pipe network layout, trenches, manholes and cost estimate. The aim is to provide a systematic underground sewerage system to replace the existing open channel drainage and improve sanitation, flooding prevention and environmental protection on campus.
This document discusses the big diameter jet (BDJ) column ground improvement method. It begins with an introduction to the BDJ method, including its three-phase jetting technology and typical specifications. Section 2 then describes several typical projects where BDJ has been used, such as metro line and port construction projects. Section 3 analyzes the strength characteristics of core samples from BDJ columns, finding their strength and stiffness are similar to or higher than other methods. The document concludes the BDJ method is well-suited for difficult ground conditions and can improve ground as effectively as other techniques.
This document presents a study on designing a water supply system for two communes in Anlong Veng District, Oddar Meanchey Province, Cambodia. The study calculates water demand, designs the pipe network layout including pipe diameters, and selects an appropriate pump system. Key results include a total pipe length of 23,199 meters using HDPE pipes from 63mm to 200mm in diameter. The total daily water demand is calculated at 1,860 cubic meters. An EBARA model 3D 65-160/9.2 pump is recommended. The study concludes with recommendations to directly survey population data and consider a water tank to reduce pumping energy.
This document discusses the design of a sewerage system for an area made up of 25% Nirala south site and 75% Toronto, Canada. Key aspects of the design include using pipes ranging from 150mm to 575mm in diameter, with total pipe lengths and numbers provided. Assumptions made in the design include domestic wastewater flow rates and formulas used. The document also discusses a visit made to the KUET water treatment plant and provides details about its operations and components.
- Morphometric analysis of the Watershed is considered to be the most satisfactory method because it enables in
understanding of the relationship of various aspects within a drainage basin. In the present study two mini watersheds in Raichur city
have been considered Mini-watershed 1 with an area of 519.32 km2 with highest order stream of 6 it flows through north of city and it
joins the streams of Krishna, Mini –Watershed 2 with an area of 360.97 km2 with highest order stream of 5 it flows through south of
city and joins Tungabhadra streams. The values of Stream frequency is 1.07 and 1.03, Form factor 0.35and 0.53, Shape factor 2.84 and
1.90, Elongation Ratio 0.67 and 0.82, Circularity Ratio 0.27 and 0.42, Drainage density 1.26 and 1.30, Length of overland flow 0.40 and
0.38 for Mini-watershed 1 and Mini-watershed 2 respectively
IRJET- Geomorphological Analysis of Two Mini-Watersheds in Raichur City K...IRJET Journal
This document analyzes the geomorphology of two mini-watersheds in Raichur City, Karnataka, India through quantitative morphometric analysis using GIS tools. Morphometric parameters were calculated for each watershed such as stream order, stream length, bifurcation ratio, drainage density, form factor, shape factor, compactness coefficient and more. Watershed 1 has an area of 519.32 km2 and Watershed 2 has an area of 360.97 km2. The results found Watershed 1 has a drainage density of 1.26 and length of overland flow of 0.40, while Watershed 2 has a drainage density of 1.30 and length of overland flow of 0.38.
“HYDRAULIC AND HYDROLOGICAL IMPACT ON BRIDGE”IRJET Journal
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FEASIBILITY STUDY OF TILA NADI HYDROPOWER PROJECT, JUMLA
1. KATHMANDU UNIVERSITY
School of Engineering
Department of Civil Engineering
Final Presentation
on
FEASIBILITY STUDY OF TILA NADI HYDROPOWER PROJECT,
JUMLA
Batch: 2016
Presented By (Group-5)
Anupras Niraula (020688-16)
Kamal Tolangi Rai (020698-16)
Anuska Ranabhat (020699-16)
Pratap Bikram Shahi (020702-16)
Anish Shakya (020703-16)
Aadarsha Ram Shrestha (020704-16)
Project Supervisor
Er. Manish Prakash
Assistant Professor
3/23/2021
2. OUTLINE OF PRESENTATION
1. INTRODUCTION
2. RATIONALE
3. OBJECTIVES
4. LIMITATIONS
5. METHODOLOGY
6. TOPOGRAPHICAL STUDY
7. GEOLOGICAL STUDY
8. HYDROLOGICAL STUDY
9. ALIGNMENT STUDY
10. HYDROPOWER COMPONENTS
11. ECONOMIC ANALYSIS
12. SOCIO-ECONOMIC STUDY
13. ENVIRONMENTAL STUDY
14. WATER SUPPLY DESIGN
15. CONCLUSIONS AND
RECOMMENDATIONS
16. WORK SCHEDULE
3/23/2021
2
3. 1. INTRODUCTION
1.1 Tila Nadi Hydropower Project
• Located 800 km west from
Kathmandu at Tila Gaupalika, Jumla,
Karnali Province.
• Site can be accessed from Nepalgunj
via Karnali Highway (H13).
• The gauging station (Station no. 220)
is about 1.5 km from Nagma Bazar of
Kalikot district.
• Estimated Power Capacity: 28.80 MW
3/23/2021
3
Fig 1.1: Topographic Map of Project Site
Source: Department of Survey, Nepal
Tila Nadi
4. 2. RATIONALE
Hydropower
i. Jumla is one of the five districts not
connected to the national grid.
ii. Out of 19,291 households in Jumla
only 5,656 households have electricity
access.
iii. There are few micro and mini
hydropower plants that do not meet
the electricity demand completely.
Integration of Water supply
i. Jumla has been listed in category A
(i.e. High risk) for diarrheal cases.
ii. Ensures good quality of drinking
water.
iii. Decreases the chance of conflict over
the water right between water users
and power generators.
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4
5. 3. OBJECTIVES
Primary Objectives:
1. To conduct the feasibility study of
Hydropower in Tila Nadi.
2. To finalize the best alignment for the
hydropower.
3. To design hydraulic components on the
basis of selected alignment.
4. To perform economic analysis of the
project.
5. To perform socio-economic analysis of
the project area.
Secondary Objective:
1. To design transmission and distribution
network of water supply system if
discharge deemed sufficient.
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5
6. 4. LIMITATIONS
1. The accuracy of the design of the project is limited to the accuracy of freely
available SRTM (30m) DEM.
2. Project was only designed based on discharge data available from DHM.
3. All the other data used were based on secondary source of data collection.
4. The values of sediment diameter and properties were assumed in absence of field
data.
5. The prospect of the project to be PROR or storage type was not evaluated.
6. The components were designed only hydraulically and were not structurally
analyzed.
7. The estimate of quantity and cost are in lump sum which may not be technically
accurate.
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6
7. 5. METHODOLOGY
3/23/2021
7
1. Data
Collection
2. Desk Study &
Consultation
3. Topographical &
Hydrological Study
4. Hydraulic Design
of the hydropower
components
5. Selection &
Design of
Turbine
6. Design of
Powerhouse & Draft
Tube
7. Economic
Analysis
8. Socio-
Economic Study
9. Environmental
Study
10. Water
Supply Design
8. 6. TOPOGRAPHICAL STUDY
1. Topographical study of the site was
done using:
i. Digital Topographic Map of the
project site purchased from
Department of Survey .
ii. Digital Elevation Model (DEM)
of 3 Arc second used to create
contour map.
3/23/2021
8
7. GEOLOGICAL STUDY
2. The region majorly consists of gneisses
and schists.
3. The river banks have alluvial deposits of
boulders and sand, composed mainly of
granite, quartzite, gneiss, schist,
dolomite and amphibolite.
1. The area consists of two distinct
rock type viz., Proterozoic Lesser
Himalayan Metasediments underlain
by the Neoproterozoic to Palaeozoic
Higher Himalyan Crystallines
separated by the MCT.
Fig 7.1: Rock classification of catchment area
Source: NP Soter
9. 3/23/2021
9
1. Catchment area : 1749.31 sq.km
2. Average annual precipitation : 819.48mm
(Thiessen Polygon method)
3. Q40 for design : 37 m3/s
4. Flood return period:
I. Gumbel’s Method:
𝑥𝑇 = 𝑥 + 𝐾𝜎𝑛−1
Q100= 459.21m3/s
II. Log Pearson Distribution III Method:
z= log(x), 𝑧𝑇 = 𝑧 + 𝐾𝑇𝜎𝑧
𝜎𝑧 =
∑ 𝑧−𝑧 2
𝑁−1
Q100= 484.14 m3/s
8. HYDROLOGICAL STUDY
5. Basin Characteristics:
S.N
Elevation
(m)
Area
(km2)
% of
given
elevation
Perimeter
(km)
1 Below 3000 57.08 3.00 487.00
2
Between
3000 to
5000
1282.63 73.00 753.00
3 Above 5000 409.59 23.00 165.00
Whole
Catchment
1749.31 100.00 248.79
13. S.N Particulars Alignment-I Alignment-II Remarks
1 Location
Intake
29˚13’13” N, 81˚56’31.57” E
(RL = 2153 amsl)
29˚12’00” N, 81˚54’57.6” E
(RL = 2165 amsl)
Salient feature
Powerhouse
23˚12’4” N, 81˚55’30” E
(RL = 2248 amsl)
23˚13’8.4” N, 81˚56’31.2” E
(RL = 2060 amsl)
2 Gross Head 95m 105m Alignment-II
3 Accessibility
Connected to Karnali
Highway
No road access Alignment-I
4 No. of bends
Only one major bend at
1.88km d/s from headwork
Has got multiple bends Alignment-I
5 No. of streams crossing
No stream crosses the
alignment
Five streams cross the
alignment
Alignment-I
6
Power generation (ⴄ =
85%)
28.80MW 32.40MW Alignment-II
3/23/2021
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9.1 Alignment Comparison
14. 3/23/2021
14
S.N Particulars Alignment-I Alignment-II Remarks
7 Total length of alignment 3.64 km 3.82 km Alignment-I
8 Effect on forest No adverse effect on forest Trees need to be cut-down Alignment-I
9 Effect on human
settlement
No damage to human
settlement
No damage to human
settlement
Alignment-I & -II
10 Slope Less steep (wider contours) More steep (crowded
contours)
Alignment-I
• Thus, Alignment-I is selected (available discharge is 37 m3/s)
• The hydropower plant is a Medium head (60-150m) and Medium capacity plant (25-
100MW) on the basis of head and capacity respectively.
15. 9.2 Comparison Between Pipe Vs. Canal
i. Design of canal required higher water
velocity which could lead to scouring and
underground seepage so was rejected.
ii. Preliminary canal design parameters
iii. As per IS 10430:2000 Criteria for Design
of Lined Canals, maximum velocity in
lined canals should not exceed 2.7 m/s.
Per the preliminary design, the velocity
was calculated to be greater than 2.7m/s,
so canal was unsuitable for the project.
Canal
Section
Dimensions(B*D) m Velocity
(m/s)
Rectangular 4.29*2.14 4.42
Trapezoidal 4.53*3.01 4.58
3/23/2021
15
9.3 Comparison Between Pipe Vs. Tunnel
i. Sufficient geological data was
unavailable.
ii. Maximum overburden pressure for the
proposed tunnel alignment was only 91m
which is very low for tunnel construction.
iii. The tunnel construction cost more than
pipe conveyance system.
325.06
300.67
285 290 295 300 305 310 315 320 325 330
Tunnel(4m dia)
Pipeline(5m dia)
Cost (Million NRs)
Particulars
Cost Comparison
Fig 9.3: Cost Comparison between Tunnel and Pipe
16. 9.4 General Layout Of Hydropower Components
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16
Fig 9.4: Components layout on selected alignment (Alignment-I)
Weir
17. 10. HYDROPOWER COMPONENTS
1. Diversion weir
2. Undersluice and Stilling Basin
3. Intake and Trashrack
4. Headrace Pipe
5. Gravel Trap
6. Settling Basin
7. Surge Tank
8. Penstock
9. Anchor Blocks and Support Piers
10. Turbine Selection
11. Powerhouse and Draft Tube
3/23/2021
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18. 10.1 Diversion Weir
i. Location:
Latitude: 29˚13’11.5” N,
Longitude: 81˚56’32.34” E
ii. Type: Ogee-shaped
iii. Height of weir: 12m
iv. Length of weir crest: 117m
v. Width of weir base: 18m
vi. Average RL of river bed = 2153m
amsl
vii. RL of crest level = 2165m amsl
vii. Head Over Crest,
𝐻𝑜 =
𝑄
𝐶𝑑𝐿𝑤
2
3
=
484.139
2.2∗117
2
3
= 1.53𝑚
vii. RL of D/S = 2149m amsl
3/23/2021
18
20. Fig 10.2: Cross-section of Ogee-shaped diversion weir with
stilling basin
3/23/2021
20
RL : Reduced Level, HFL : High Flood Level
NWL : Normal Water Level
21. 10.2 Undersluice and Stilling Basin
Undersluice
i. 20% of 100 years return period flood
discharge for undersluice (Q)= 96.83
m3/s
ii. Total Length of undersluice crest (L)
= 10.5 m
iii. Length of Undersluice crest (Lw) =
8m
iv. No of bays = 2
v. Width of each bay = 4m
vi. Total width (B) = 8m
vii. Head Over Crest, 𝐻𝑜 = 2.7𝑚
viii.Height of opening of undersluice
=1.5m
3/23/2021
21
Stilling Basin
i. Height of chute block = 0.25m
ii. Width of chute block = 0.18m
iii. Spacing of chute block = 0.25m
iv. Spacing of first chute block = 0.12m
v. Height of dented sill = 0.80m
vi. Width of dented sill = 0.60m
vii. Spacing of dented sill = 0.60m
viii.Top width of dented sill = 0.08m
23. 10.3 Intake and Trashrack
Intake
i. Location:
Latitude: 29˚13’13” N,
Longitude: 81˚56’31.57”E
ii. Type: Bell-mouth (submerged)
iii. Design discharge, Q = 37m3/s and
accounting 20% additional flow
44.4m3/s
iv. No of intake = 2
v. Discharge through each intake = 22.2
m3/s
vi. Diameter of pipe (D) = 3.5 m
vii. Total height = 5.50 m
viii.Width of opening = 2.92m
ix. Angle of inclination of headrace
pipe = 0.69
x. Suction head to avoid vortex
formation = 4.4m
xi. Head loss at intake, Hf = 0.007m
xii. Invert level = 2155 amsl (2m above
river bed)
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23
24. Trashrack:
i. Material = Steel
ii. Spacing of trash bars =
100mm
iii. Thickness of bars = 20mm
iv. Angle of inclination with the
horizontal = 70⁰
v. Submerged depth of trashrack
= 5.50m
vi. Width of end piers = 0.3m
vii. Width of pier between 2 bell-
mouth intakes = 0.5 m
viii.Head loss, Hf = 0.0167m
3/23/2021
24
Fig 10.4: Bellmouth Intake with Trashrack
26. 10.4 Headrace Pipeline
I. Intake to Gravel trap
i. Diameter = 3.5m
ii. Length = 40m
iii. Thickness = 16mm
iv. Head loss in pipe, hf = 0.03m
v. Slope = 1 in 40
II. Gravel trap to Settling basin
i. Diameter = 5m
ii. Length = 1102m
iii. Thickness = 16mm
iv. Head loss in pipe, hf = 0.665m
v. Slope = 1 in 400
3/23/2021
26
III. Settling basin to Surge tank
i. Velocity = 1.88 m/s
ii. Diameter of pipe = 5 m
iii. Length = 1930m
iv. Thickness = 16mm
v. Frictional loss, ℎ𝑓(𝑚𝑎𝑗𝑜𝑟) = 0.631m
vi. Bend Loss, ℎ𝐿(𝑏𝑒𝑛𝑑) = 0.3783 𝑚
vii. Entrance Loss, hL(entrance) = 0.009 𝑚
viii.Slope = 1 in 217
ix. Pipe Diameter Optimization using DOED
Guideline:
𝐷 = 1.12
𝑄0.45
𝐻𝑛
0.12 = 1.12
370.45
9.030.12
= 4.4𝑚
27. 3/23/2021
27
Fig 10.7: Headrace Pipeline Optimization Curve
0.00
500.00
1000.00
1500.00
2000.00
2500.00
2.00 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 4.25 4.50 4.75 5.00 5.25
Cost
(Nrs.)
Millions
Diameter (m)
Total Cost Energy Loss Cost Penstock Construtction Cost
Headrace pipe Construction Cost
28. 10.5 Gravel Trap
i. Location:
Latitude: 29° 13' 1.2"N,
Longitude: 81° 56' 16.8"E
ii. Design discharge, Q = 37m3/s and
accounting 20% additional flow
44.4m3/s
iii. Size of particles to be settled = 2mm
iv. No. of bays = 2
v. Width of gravel trap = 5 m
vi. Height of gravel trap = 7.62 m
vii. Inlet angle = 30°
viii.Outlet Angle = 45°
viii. Settling velocity = 0.3 m/s
ix. Detention time = 58.47s
x. Total length of gravel trap = 38m
xi. Suction head = 2.62m
xii. Type of flushing = Continuous
xiii. Size of flushing opening = 2m*1m
xiv. Slope of flushing canal = 0.002
xv. Flushing velocity = 2.96 m/s
xvi. Inclination of Hopper (Lateral Slope)
= 30⁰
xvii.Vertical height of Hopper = 2.6m
xviii.Total head loss in Gravel trap =
3.664*10-5 m
3/23/2021
28
31. 10.6 Settling Basin
i. Location:
Latitude: 29° 12' 50.4"N
Longitude: 81° 55' 55.2"E
ii. Discharge = 1.2*37 = 44.4 m3/s
iii. Particle size to be settled = 0.2mm
iv. Theoretical Settling velocity = 0.0217
m/s and for actual shape of sediment
only 65% of theoretical velocity is
taken i.e. 0.0142m/s
v. No. of bays = 2
vi. Total length of settling basin = 273.3m
vii. Total Width of settling basin = 37.8m
viii.Total depth of settling basin = 12m
ix. Freeboard = 1m
x. Thickness of baffle wall = 0.8m
xi. Thickness of side wall = 0.5m
xii. Suction Head = 3m
xiii.Detention time = 12min
xiv. Size of flushing canal = 4m*2m
xv. Flushing discharge = 0.2*40.7 =
8.9m3/s
xvi. Total head loss (Transition + Settling
zone loss) = 0.0489m
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35. 10.7 Surge Tank
i. Location:
Latitude: 29° 12' 10.8"N
Longitude: 81° 54' 54"E
ii. Discharge = 37 m3/s
iii. Diameter of surge tank = 17m
iv. Thickness of wall = 0.5m
v. Max. up surge up on 100% load
rejection = +7.45m
vi. Max. down surge up on 100%
demand = -5.96m
vii. Height of surge tank = 21m
viii. Freeboard = 3 m
ix. Submergence head = 5.4m
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Fig 10.14: Surge Tank
0.5m Thickness
17m ϕ
36. 10.8 Penstock
i. Material: Steel (IS 226/75)
ii. Gross head: 95m
iii. Length of penstock: 246.77m
iv. Thickness of pipe: 20mm
v. Factor of safety: 3
vi. Diameter of penstock: 3.6m
vii. Head loss in penstock: 0.41m
viii.Assumed Project life = 50 years
ix. Total Cost of Penstock = Rs.
90,465,688.36
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36
0.00
50.00
100.00
150.00
200.00
250.00
300.00
350.00
2.00 2.25 2.50 2.75 3.00 3.25 3.50 3.75 4.00 4.25 4.50 4.75 5.00 5.25
Cost
(Nrs.)
Millions
Diameter (m)
Penstock Diameter Optimization Curve
Total Cost Energy Loss Cost Penstock Construtction Cost Optimum
Fig 10.15: Penstock optimization graph (Diameter vs cost)
Penstock Construction Cost
37. Anchor Blocks
A. General Section
i. Height of Anchor Block in U/S face
(H) = 8 m
ii. Height of Anchor Block in D/S face
(h) = 6 m
iii. Length of Anchor Block (L) = 7 m
iv. Width of Anchor Block (W) = 8 m
v. No. of Anchor Blocks = 3
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37
10.9 Anchor Blocks and Support Piers
B. Critical Section
i. Height of Anchor Block in U/S face
(H) = 8 m
ii. Height of Anchor Block in D/S face
(h) = 6 m
iii. Length of Anchor Block (L) = 13 m
iv. Width of Anchor Block (W) = 15 m
v. No. of Anchor Blocks = 2
40. Support piers
i. Slant Height of Support Pier in U/S face =
2.3 m
ii. Slant Top Length of Support Pier = 0.5 m
iii. Base Length of Support Pier = 2 m
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40
iv. Width of Support Pier = 9 m
v. Slant Base Length of Support
Pier = 2.21 m
vi. No. of support pier = 8
Fig 10.18: Support Piers
41. 10.10 Turbine Selection
I. According to Head and Discharge
1. Gross head = 107 m
2. Net head = 93.49m
3. Efficiency of turbine = 85%
4. Discharge =37 m3/s
5. Power generated = 28.80 MW
6. The turbine selected is Francis turbine
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41
7. Number of poles = 12
8. Frequency = 50 Hz
9. Specific Speed = 196.40 rpm
10. Number of units = 3
11. Diameter of runner = 2.80m
42. 3/23/2021
42
Fig 10.19: Turbine Selection Chart based on head and Discharge
(Source: Chen, Jian & Yang, H.X. & Liu, C.P. & Lau, C.H. & Lo, M. (2013). A novel vertical axis water turbine for power
generation from water pipelines).
43. Dimensioning of power house
i. Location:
Latitude: 29° 12' 3.6"N
Longitude: 81° 54' 57.6"E
ii. Width of column (w) = 0.8m
iii. Depth of column (d) = 0.8m
Length
i. Unit Spacing = 17.43 m
ii. Number of units = 3
iii. Length of erection bay = 13.74 m
iv. Total Length = 75.63 m
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43
Width
i. D/S from central axis of turbine = 7.19 m
ii. U/S from central axis of turbine = 9.44 m
iii. Total width of Power House = 18.23 m
Height
i. Height of Turbine floor = 10.50 m
ii. Clearance for largest package = 8 m
iii. Roof clearance = 4 m
iv. Height of generator room = 14.80m
v. Height of draft tube chamber = 6.87 m
vi. Total Height = 32.17m
10.11 Powerhouse and Draft Tube
44. Draft Tube
i. Submergence Head, 𝐻𝑠 = −0.24 𝑚
i.e. the central line of turbine should lie at least 0.24m below the tailrace water level
ii. Draft Tube Dimensions:
iii. Exit Velocity =
𝑄
𝐵ℎ
=
12.33
8.25∗2.58
= 0.58𝑚/𝑠
iv. Minimum submergence required at exit =
𝑉𝑒
2
2𝑔
= 0.03 𝑚
v. The total volume of pondage was 8280 m3 and area 6073.47 m2.
vi. The water level was maintained at 2058 amsl.
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Description Dimensions
Outlet width, B 8.25m
Draft tube depth, H 6.87m
Length of draft tube, L 13.19m
Outlet height, h 2.58m
49. 10.12 Hydraulic Gradient Line
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Fig 10.24: Hydraulic Gradient Line
RL : Reduced Normal Level, EGL : Existing Ground Level, TEL : Total Energy Line
NWL : Water Level, HGL : Hydraulic Gradient Line
50. 11. ECONOMIC ANALYSIS
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50
S.N. Detail Breakdown
Amount
(NRs)
Amount in words (NRs)
%
coverage
1 Civil Construction Cost 1,548,963,825
One billion, five hundred forty-eight million, nine
hundred sixty-three thousand, eight hundred and twenty-
five
32.6%
2
Hydro-Mechanical
Equipment
965,500,200
Nine hundred sixty-five million, five hundred thousand
and two hundred
20.3%
3
Electro-Mechanical
Equipment
1,000,000,000 One billion 21.1%
4
Project Development
Cost
70,289,281
Seventy million, two hundred eighty-nine thousand, two
hundred and eighty-one
1.5%
5 Land Purchase 70,289,281
Seventy million, two hundred eighty-nine thousand, two
hundred and eighty-one
1.5%
6
Site Office and
Infrastructure
Development Cost
175,723,202
One hundred seventy-five million, seven hundred
twenty-three thousand, two hundred and two
3.7%
11.1 Detail Project Cost Breakdown
51. 3/23/2021
51
S.N. Detail Breakdown
Amount
(NRs)
Amount in words (NRs)
%
coverage
7
Office Equipment and
Vehicle
70,289,281
Seventy million, two hundred eighty-nine thousand, two
hundred and eighty-one
1.5%
8
Environment
Mitigation
17,572,321
Seventeen million, five hundred seventy-two thousand,
three hundred and twenty-one
0.4%
9
Project Engineering
and Supervision
105,433,921
One hundred five million, four hundred thirty-three
thousand, nine hundred and twenty-one
2.2%
10 VAT 523,127,971
Five hundred twenty-three million, one hundred twenty-
seven thousand, nine hundred and seventy-one
11.0%
11 Contingencies 201,203,066
Two hundred one million, two hundred three thousand
and sixty-six
4.2%
Total 4,748,392,349
Four billion, seven hundred forty-eight million, three
hundred ninety-two thousand, three hundred and
forty-nine
100.0%
52. 32.6
20.3
21.1
1.5
1.5
3.7
1.5
0.4
2.2
11
4.2
Detail Cost Breakdown Civil Construction Cost
Hydro-Mechanical Equipment
Electro-Mechanical
Equipment
Project Development Cost
Land Purchase Cost
Site Office & Infrastructure
Development Cost
Office Equipment & Vehicle
Environmental Mitigation
Project Engineering &
Supervision
VAT
Contegencies
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Fig 11.1: Percentage coverage by various components
53. 11.2 Annual Energy Generation:
182.91 GWh
11.3 Annual Revenue: NRs 1093.81
million
11.4 Annual Expense: NRs 123.33
million
11.5 Construction Period: 3 years
11.6 Generation Period: 30 years
11.7 Project Investment: Equity=30%
Loan= 70%
11.8 Loan Interest: 4% per annum
11.9 Income Tax: 20% of the income
11.10 Discounted Rate: 8% per annum
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Fig 11.2: Discounted Payback Period
-5000
-4000
-3000
-2000
-1000
0
1000
2000
3000
4000
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33
Discounted
Cost
(NRs
in
Millions) Years
Discounted Payback
Cost
11.11 Net Present Value: NRs 3133.6
million>1(Profitable)
11.12 IRR: 15%> 8% discount rate(Profitable)
11.13 B/C Ratio: 1.27>1(Profitable)
11.14 Discounted Payback Period: 12 years
54. 11.15 Sensitivity analysis
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54
0.6
0.8
1.0
1.2
1.4
1.6
1.8
-30% -20% -10% 0% 10% 20% 30%
B/C
Ratio
Variation(%)
Sensitivity Analysis for B/C ratio
Cost Variation Reveue Variation
1000
1500
2000
2500
3000
3500
4000
4500
5000
-30% -20% -10% 0% 10% 20% 30%
Net
Present
Value
in
million
NRs
Variation(%)
Sensitivity Analysis for NPV
Cost Variation Reveue Variation
Fig 11.3: Sensitivity analysis on B/C for cost and
Revenue Variation
Fig 11.4: Sensitivity of project on NPV on cost and
Revenue Variation
55. Jumla District
i. Population: 108,921
ii. Population density: 43/km2
iii. Literacy: 50%
iv. Total number of Household: 19,291
v. There are altogether 295 educational
institutes
vi. 1 governmental hospital, 20
secondary posts and 8 health posts
vii. The major castes living in the two
districts were Brahmins, Thakuri,
Chhetris, Lama and Dalits.
vii. Major occupations: Fishery,
Agriculture and Gravel mining
Tila Rural Municipality
i. Total Population: 13,607
ii. Area: 175 km2
Kalikot District
i. Population: 136,948
ii. Population density: 79/km2
iii. Literacy: 67.14%
iv. Total number of household: 23,008
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12. SOCIO-ECONOMIC STUDY
56. 3/23/2021
56
98.58
1.42
Jumla's distribution of fuel for cooking % (2011)
Firewood others
29.32
0.32
0.02
44.31
25.40
0.63
% Source of lighting (Jumla)
Electricity Kerosene Bio-gas
Solar Others Not Stated
Fig 12.2: Distribution of household use of fuel for
cooking in Jumla District
Fig 12.1: Sources of Lighting in Jumla District
57. 3/23/2021
57
11.62
1.43
0.04
37.14
49.17
0.60
% Source of lighting (Kalikot)
Electricity Kerosene Bio-gas
Solar Others Not Stated
Fig 12.4: Sources of Lighting in Kalikot District
Fig 12.3: Sources of water supply in Jumla District
80.04
0.14
0.41 14.8
3.59
0.38 0.62
Jumla Water Supply Situation % (2011)
Tap/Pipe Covered Well Uncovered Well
Spout Water River/Stream Others
Not Stated
58. 3/23/2021
58
98.58
2.02
% Distribution of fuel for cooking
(Kalikot)
Firewood others
58.01
0.97
1.45
34.85
3.87
0.27 0.58
Kalikot Water Supply SItuation % (2011)
Tap/Piped Covered Well Uncovered Well
Spout Water River/stream Others
Not Stated
Fig 12.5: Distribution of household use of fuel for
cooking in Kalikot District
Fig 12.6: Sources of water supply in Kalikot District
59. 12.1 Positive Impacts And Promotion
S.N. Positive Impacts Promotion Measures
1 The problem of load shedding will be
significantly decreased.
Proper management of electricity generated
along with subsidized rates to local population.
2 Generation of employment opportunities. Recognizing population in need of employment
created by the hydropower.
3 Improvement in the working conditions of women
employed in local agro-processing mills as
mechanical automation replaced labor-intensive
manual processing.
Subsidizing the cost of electricity for few years
to the industries established around the project
area.
4 Improvement in different sectors such as
education, irrigation, water supply, tourism etc.
Providing separate lines to educational
institutes, conducting different vocational
training and integration of water supply.
5 Increase in local and regional economy The royalty obtained from the hydropower plant
can be invested in the same region to launch
other infrastructures of development
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60. 3/23/2021
60
12.2 Negative Impacts And Mitigation
S.N. Negative Impact Mitigation measures
1 Impact on fish migration and fishery downstream
of the dam.
Construction of fish hatchery on the d/s of the
project and limit fishing on the U/S of the
reservoir.
2 Rise in water level may cause negative impacts on
sports such as rafting.
The project will work with rafting companies to
locate new area for rafting or provide jobs for
those affected by the hydropower project.
3 Insufficient water may be available immediately at
the downstream of the project which may be used
by local population for propose of drinking,
cleaning or irrigation.
Integrating the project for water supply and
irrigation as well as release of sufficient water
d/s for the intended purposes
61. 13. ENVIRONMENTAL STUDY
i. IEE is to be conducted for hydropower
with power generation ranging from
1MW to 50MW (Schedule 1, EPR
1997)
ii. The physical and biological
environment were only studied.
iii. The study was carried on the basis of
available secondary sources like EIA
report of Karnali Highway, District
Profile of Jumla and IEE reports of
Hydropower Projects of similar nature
and scale.
iv. Jumla falls in the Sub-alpine climate
zone (elevation 3000m to 4000m)
with partly cloudy wet seasons, and
cool and mostly clear dry seasons.
v. The vegetation that grow in this
region are usually coniferous.
vi. Different valuable medicinal and
aromatic plants like Yarshaghumba,
Pachaula, Jatamashi, Sugandhawal,
Padamchal, etc. are found in this
region.
vii. Domestic animals : cow, yak, buffalo,
sheep, pig and goat
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62. 13.1 Positive Impacts And Promotion
S.N. Positive Impacts Promotion Measures
1 Enhances aquatic habitat in dry season
and prevents damage to the vegetation
during wet season
1. Providing control in the fluctuation in water flow
2. Release of sufficient water in the d/s region esp in
the dry season
2 Reduction in greenhouse gas emission. 1. Introducing the local people with electrical
equipment and induction stoves
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vii. Wild animals : musk deer, red panda, snow leopard, Himalayan black
bear, Indian leopard, jackal, Himalayan tahr, yellow-throated
marten, otter, dhole, gray langur, and rhesus macaque ghoral
viii.Birds : Himalayan Snowcock, Chukar Partridge, Himalayan Monal, Kalij
Pheasant, Blood pheasant, Great-crested, Black-necked Grebes, etc.
63. 13.2 Negative Impacts And Mitigation
S.N. Negative impacts Magnitude Duration Mitigation measures
1 Cut and fill have to be
carried out that might change
the topography of the site
Moderate Long
term
1. Construction of slope stabilizing
structures.
2. Proper landscaping and re-vegetation
inside the project’s premises.
2 Land acquisition that mainly
includes cultivable lands
Moderate Long
term
Paying proper compensation to the land
owner.
3 Generation of dust and noise
due construction works like
ground excavation, levelling,
etc.
Moderate Short
term
1. Water sprinkling in the excavation
sites.
2. The spoil will be backfilled and
compacted with required watering.
3. Restriction of noise generating
activities at night.
4 Aquatic ecosystem in the
curtailed river section will be
disturbed
Moderate Long
term
Discharging sufficient water to the d/s in
dry seasons.
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64. 3/23/2021
64
S.N. Negative
impacts
Magnitude Duration Mitigation measures
5 Reduction in
water quality
Moderate Long term 1. Proper disposal of generated concrete waste in pits
and filled with soil.
2. Proper care will be taken not mix the waste
materials into the river.
3. Proper toilets and shower rooms will be provided
to the workforce.
4. Garbage and solid wastes produced by the labor-
camp will be dumped safely away from water
bodies.
5. Good construction practices and site management
will be adopted to avoid impacting soil and ground
water, and pollution of water bodies.
6. Prohibition on open defecation by the workers.
7. Spilling of lubricants and oils will be minimized
through proper care in storage and handling of the
transformers and containers of lubricants and oils.
65. 14. WATER SUPPLY DESIGN
14.1 Alignment Study
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65
Conveyance Pipe
Tila Nadi
Settling Basin
Fig 14.1: Alignment-I from Settling Basin
Alignment-I
67. S.N Particulars Alignment-I Alignment-II Remarks
1 Intake Location Settling Basin Tailrace
2 Period of water withdrawal
6hrs (3hr+3hr) 24hrs Alignment-II
3 Total Length 2.6 km 386 m Alignment-II
4 Diameter (Preliminary) 225 mm 140 mm Alignment-II
5
Number of Pressure Break
Valve/Tank required
1 Nil Alignment-II
6 No. of Reservoir Tank (RVT)
2 1 Alignment-II
7 Reservoir Capacity 207.26 m3 (RVT1)+ 96.72
m3 (RVT2)
96.72 m3 (RVT1) Alignment-II
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14.2 Alignment Comparison
• Thus, Alignment-II is selected for withdrawal of water for purpose of water supply.
68. 14.3 Design Of Water Supply System
1. Number of households = 284
2. Present Population (P0) = 1488
3. Population Growth Rate = 0.93%
4. Design year = 21 years
5. Population after 21 years (P21) =
𝟏𝟖𝟎𝟖
6. Maximum demand factor = 1.8
7. Total Domestic Demand = PT*per
capita demand = 180800 lpd
8. Total Institutional demand = 3430
lpd
9. Total demand = 2.13 l/s
10. Maximum demand = 1.8*Total demand =
3.84 l/s
11. Sub-Main Distribution Line Diameter = 20
mm
12. Transmission/Supply main Line Diameter =
140 mm
13. Total Length of Transmission Line =
385.93m
14. Public Tap was designed as per the general
design provided in the “Technical Training
Manual No.5” (Local Development
Department, Ministry of Home and
Panchayat, SATA and UNICEF)
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68
71. 14.4 Reservoir Tank & Slow Sand Filter
Reservoir Tank
i. The total capacity of the reservoir required = 96.72 m3
ii. Provided volume of tank = 98.17 m3
iii. Diameter of Reservoir Tank = 5m
iv. Depth of Reservoir Tank = 5m
v. Demand pattern:
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71
Time % Demand
00:00 A.M.-04:00 A.M. 0
04:00 A.M.-09:00 A.M. 40
09:00 A.M.-15:00 P.M. 30
15:00 P.M.-17:00 P.M. 10
17:00 P.M.-21:00 P.M. 20
21:00 P.M.-00:00 A.M. 0
72. 3/23/2021
72
Design of Slow Sand filter
1. Rate of filtration = 150 liter/hr*m2
2. Total surface area of filter required =
92.16 𝑚2
3. Number of filter bed provided = 3
(2 operational while 1 as a standby)
4. Area of each filter unit = 46.08 m2
5. Width of a single unit = 5m
6. Length of the filter = 10m
7. Depth of Supernatant Water Layer = 1m
8. Total Depth of filter = 2.6m
(including 0.2m free board)
9. Specification of sand
i. Effective size: 0.15-0.30 mm
ii. Uniformity coefficient: Max.5,
preferably below 3
74. 15. CONCLUSIONS & RECOMMENDATIONS
15.1 Conclusions
i. The hydropower potential of Tila Nadi
Hydropower project is found to be 28.8 MW
with design discharge Q40 of 37 m3/s and net
head of 93.48 m.
ii. Alignment at the right side of Tila Nadi is
found to be more feasible than the alignment
at the left side.
iii. Hydraulic design of components of
hydropower have been done following
DOED standards/guidelines and IS where
needed.
iv. The total estimated cost of the project is
NRs. 4,748,392,349 /-
v. Benefit cost (B/C) ratio of this project is
1.23>1(economically feasible).
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74
vi. With the simple payback period of 9
years and positive value for net present
value, the project is found to be
financially feasible as well.
vii. Only two households will require
relocation so there is likely to be less
social issues.
viii. No adverse effects to the environment.
ix. Water is supplied from tailrace pondage,
and average daily demand is 3.84 l/s and
design period is 21 years.
x. A dead tree system with minimum 10m
water pressure at any point for water
distribution system with maximum pipe
diameter of 90 mm and minimum
diameter of 20 mm.
75. 3/23/2021
75
15.2 Recommendations
i. Actual field survey should be conducted.
ii. Hydraulic models of the components should be made and tested for further
optimization and design improvement.
iii. Feasibility of a project as PROR or Storage type can be conducted based on
field/primary data.
iv. Design of the treatment plant should be done after monitoring of the water quality
of the pondage water.
v. The self-sustainability of the water supply scheme should be determined by
conducting household socio-economic study.
vi. Placement of tap stand can be further made accurate by use of actual field data.
76. 16. WORK SCHEDULE
S.N Work Progress
May June July August Sep.
3 4 1 2 3 4 1 2 3 4 1 2 3 4 1 2 3 4
1 Literature review
2 Consultation and discussion
3 Proposal submission &
defense
4 Desk work
5 Mid-term presentation
6 Final report submission
(Draft)
7 Final project defense
Works completed
Works ongoing
3/23/2021
76
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