Installation of auxiliary water supply network in the department of agricultural and bio-environmental engineering
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Water Supply Systems
- 2.2Historical Development of Water Networks
- 2.3Importance of Auxiliary Water Supply Networks
- 2.4Design Considerations for Auxiliary Water Systems
- 2.5Case Studies on Auxiliary Water Networks
- 2.6Challenges in Implementing Auxiliary Water Networks
- 2.7Technologies for Auxiliary Water Supply
- 2.8Regulation and Standards for Water Systems
- 2.9Economic and Environmental Impacts
- 2.10Future Trends in Water Supply Systems
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Design and Approach
- 3.2Data Collection Methods
- 3.3Sampling Techniques
- 3.4Data Analysis Procedures
- 3.5Ethical Considerations
- 3.6Research Limitations
- 3.7Validity and Reliability of Research
- 3.8Research Timeline and Budget
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Overview of Findings
- 4.2Analysis of Data
- 4.3Comparison of Results with Literature
- 4.4Discussion on Design Considerations
- 4.5Implications of Findings
- 4.6Recommendations for Implementation
- 4.7Areas for Future Research
- 4.8Conclusion of Findings
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Summary of Research
- 5.2Conclusion and Interpretation of Results
- 5.3Contributions to the Field
- 5.4Practical Applications and Recommendations
- 5.5Implications for Policy and Practice
- 5.6Reflections on the Research Process
- 5.7Limitations and Suggestions for Future Research
- 5.8Closing Remarks
Thesis Abstract
Abstract
The installation of an auxiliary water supply network in the Department of Agricultural and Bio-environmental Engineering aims to enhance water distribution and management within the department's premises. This project involves the design and implementation of a secondary water supply system to supplement the existing infrastructure. Through the integration of additional pipelines, storage tanks, and pumping stations, the auxiliary network will improve water availability for various research activities, irrigation purposes, and laboratory requirements. The primary objective of this project is to ensure a reliable and sustainable water supply within the department by reducing dependency on the main municipal water line. The auxiliary network will provide backup support during water shortages, maintenance periods, or emergencies, thus ensuring uninterrupted operations and research activities. By optimizing water distribution and storage capabilities, the system will enhance the department's resilience to fluctuations in the main water supply and contribute to overall water efficiency. The design of the auxiliary water supply network will involve a comprehensive assessment of water demands, hydraulic calculations, pressure requirements, and environmental considerations. Special attention will be given to the selection of materials, technologies, and equipment to ensure durability, efficiency, and cost-effectiveness. The layout and configuration of the network will be optimized to minimize energy consumption, reduce water losses, and facilitate ease of maintenance. Implementation of the auxiliary water supply network will involve the construction of additional pipelines, installation of storage tanks, and integration of pumping systems. The project will also include the development of a monitoring and control system to optimize water flow, pressure regulation, and leak detection. Regular maintenance schedules and operational protocols will be established to ensure the long-term performance and reliability of the auxiliary network. Overall, the installation of an auxiliary water supply network in the Department of Agricultural and Bio-environmental Engineering represents a proactive approach to enhancing water management practices and ensuring operational continuity. By diversifying water sources and improving distribution infrastructure, the project aims to support research activities, experimental facilities, and educational programs within the department. The successful implementation of the auxiliary network will contribute to sustainable water use, resource conservation, and resilience to water-related challenges in the agricultural and bio-environmental engineering field.
Thesis Overview
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</p><p><b>1.0 INTRODUCTION</b></p><p><b>1.1 BACKGROUND<br>OF THE STUDY</b></p><p>Through a constant series of research<br>and development, It was suggested that groundwater is among the purest forms of<br>natural occurring water. Hailstorm G., (2008). Therefore the utilization of<br>groundwater has become very pertinent especially in areas where modern<br>purification schemes do not exist.</p><p>Underground water is tapped via hand<br>dug wells, cancels and boreholes. Borehole involves the use of drilling rigs<br>reacl. The water bearing strata located several matter below the ground. Canals<br>are cut along designated channels proven to have a lot of near surface<br>underground water occurrence, canals are used mostly for agricultural purposes<br>in Nigeria. Water dug wells data back to the ancient days and has persisted to<br>date as the most reliable and economic source of water for rural and<br>metropolitan dwellers Stiles L, (1998).</p><p>Community health schemes in Nigeria<br>have been enhanced by the provision of different hand pump delivered<br>underground water. Some communities have big overhead tanks and the underground<br>water is delivered to such tanks by submersible pumps. In the case both the<br>bacteriological and chemical analysis are done and compared with world health<br>organization standards, to declare the borehole canal or dug well water safe<br>for human consumption.</p><p>Borehole are resistance to many forms<br>of natural and man-made disasters. Although the narrow opening at the top of<br>water source or damage to the pump components below ground than what can be<br>seen on the surface.</p><p>A borehole is a narrow that bored in<br>the ground either vertically or horizontally. A borehole may be constructed for<br>many different purposes, including the extraction of water, other liquid (such<br>as petroleum) or gasses (such as natural gas), as part of a geotechnical<br>investigation, environmental site assessment, mineral exploration, temperature<br>measurement, as a pilot hole for installing piers or underground utilities for<br>geothermal installations, or for e.g in carbon capture and storage Hellstron G;<br>(2008). Borehole is also refers to as hydraulic structure which when properly<br>designed a constructed permits the economic withdrawal of water from an<br>aquifer, Todd D.K (1980).</p><p><b>1.2 <br>STATEMENT OF THE PROBLEM</b></p><p>The borehole of the department of<br>agricultural and bio-environmental engineering Kaduna polytechnic was in a bad<br>working condition period infect the cracking, handling has been removed and the<br>chain transmission was rusted due to the action of rainfall on it. Effort where<br>made to make the borehole function able but it was discovered that the depth or<br>the borehole was shallow which resulted in water shortage during day season. It<br>was suggested after geophysical survey that a new borehole should be<br>constructed which was done to the pump mounting level. There is need to<br>distribute the water to points (places) such as the laboratories and<br>departmental lawns by providing pipe network to deliver the water.</p><p>Therefore the project is<br>to provide pipe network to deliver water to the overhead tank which supply<br>water to the departmental lawn.</p><p><b>1.3 <br>AIMS AND OBJECTIVES</b></p><p>The aims of this project is to<br>provide water supply pipe line system from the drilled pumped borehole to the<br>departmental building and connect it to a procured overhead tank.</p><p>The objectives of the project are :</p><p>i. <br> To carry out a reconnaissance survey to<br>determine the route and distances of the axillary pipe line system from the<br>borehole to the overhead tank;</p><p>ii. To estimate the quantity and<br>types of materials require;</p><p>iii. To conduct a market survey to<br>ascertain the cost of the estimated materials;</p><p>iv. To procure and install an<br>overhead tank that will be connected to the water supply system;</p><p>v. To lay down the axillary pipes<br>from the borehole to the designated point (overhead tank).</p><p>1.4<b> SIGNIFICANCE OF THE STUDY</b></p><p>The borehole water of the department<br>will serve as an easiest source of water to the laboratories and lawns will<br>supplement the constant shortage of water from the public water supply system.</p><p>Also the borehole water will serve as<br>a source of water to the neighboring departments and medical Centre.</p><p>1.5 <b>SCOPE OF THE STUDY</b></p><p>The scope of this project is limited<br>to providing pipe network from the departmental borehole to the overhead tank<br>that supplies water to the departmental lawns.</p>
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