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Prototyping a Well-Driver PUP (Purdue Utility Project) to Install Low-Cost Driven Water WellsZackariah J Horn (6632300) 11 June 2019 (has links)
<p>People living in developing
countries or undeveloped regions often do not have proper access to quantities
of safe, clean water to fulfill their daily needs. Certain members of the families, often women
and children, walk miles every day to collect surface waters that are
frequently contaminated. To improve
water availability and quality, a sustainable mechanical solution to more
safely access groundwater has been developed.</p>
<p> </p>
<p>A well-driving attachment for a
PUP (Purdue Utility Project) vehicle provides a low-cost means for installing
driven type wells in areas of high to medium water table heights. PUP vehicles have a niche in developing
countries, as they offer impressive value and utility in comparison to other
powered machines. The vehicles are built
and sourced using locally available materials with basic tooling. A hydraulic post driver has been attached to
the rear of a PUP frame to serve as an impact mechanism, driving a well point
and a series of inter-connecting pipes to serve as a permanent casing for the
well. </p>
<p> </p>
<p>Water wells were tested at four
different test sites around central Indiana, with the deepest well reaching 23
feet. This suggests that the Well-Driver
PUP can install driven water wells in areas of medium to high water tables and
may be suitable for a development setting.
Water wells can be installed on a communal basis, thus providing an
increased level of hygiene and standards of living. Low-cost driven water wells will provide a
drinking water supply that is better protected than a hand-dug well and will
reduce the likelihood of disease caused by waterborne pathogens. Development of the Well-Driver PUP prototype
and its applications will be discussed.</p>
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IMPROVEMENTS TO THE DRIVING CAPABILITIES OF A WELL-DRIVER PUP (PURDUE UTILITY PROJECT) TO INSTALL LOW-COST DRIVEN WATER WELLSGrace L Baldwin Kan-uge (7847804) 24 July 2023 (has links)
<p>In developing countries water access is not always available. In many locations around the world, people lack sufficient access of water for both drinking and domestic purposes and use unsafe water sources. Particularly in sub-Saharan Africa, women and children walk great distances to obtain access to water. People must have equitable and affordable access to safe and sufficient water that is palatable and in sufficient quantity for both drinking and domestic purposes before any other long-term economic development or social improvement can occur. This research seeks to increase access to subsurface water by improving the driving capabilities of the Well-Driver PUP (Purdue Utility Project) vehicle. The Well-Driver PUP is a low-volume manufactured utility vehicle with a hydraulic post driver mated to it in order to mechanize tube well installation. </p>
<p>Worldwide, there are many locations where the water table depth is less than 23 meters, specifically in the 10-20 meters range. These areas include sub-Saharan Africa, the Caribbean, South America, northern India, Asia, and parts of the Asia Pacific Islands. These locations are places where the Well-Driver PUP could potentially be utilized, if sufficient reliability and depth can be demonstrated on a repeatable basis. This would increase the number of locations throughout the world that the vehicle could be used to access ground water for those with limited to no current water access. Ghana is one of the many countries located within sub-Saharan Africa where the Well-Driver PUP could have a positive impact.</p>
<p>The author has had significant professional experience working in Ghana on various international development projects related to agriculture, water, sanitation, and hygiene (WASH). She has been part of international development projects in Ghana, Tanzania, and Haiti, with experience working cross-culturally since 2014. She has worked on projects specifically in Ghana for more than 9 years and has been part of more than 32 different water resource projects within the country. Therefore, consideration is specifically given to the appropriateness of the Well-Driver PUP as first piloted in Ghana. For this work, a cost analysis of using the Well-Driver PUP per depth and comparison to current driven wells in Ghana was carried-out. </p>
<p>A review of the literature was conducted. Four research questions and experiments were established. Experiment 1 carried-out three different pipe stack numerical loading studies that were simulated in Fusion 360® (Autodesk, San Rafael, CA). Load models were examined of a centered hit, a non-centered hit, and a well point only. It was shown that the average dynamic impact force applied by the driving ram was calculated to be 39 kN. FEA analysis was conducted in Fusion 360®, and it included Von Mises, safety factor, and displacement results. The average dynamic impact force that the Well-Driver PUP applies was less than both the yield stress and ultimate tensile strength of ASTM A53 steel, indicating that no deformation or breakage of the well point should be expected. </p>
<p>Experiment 2 included increasing the weight of the driving ram, through the addition of weight plates. A series of wooden fence post installations using these new weight additions was conducted. This experiment allowed for a regression model to be developed predicting the impact of weight added to the driving ram, the drop height of the ram, and the soil moisture content, on the driving depth of the vehicle. The MLR model included the penetration depth (Y), weight added (X<sub>1</sub>), drop height (X<sub>2</sub>), and soil moisture content (X<sub>3</sub>). The model coefficient estimates were determined, and the predictor variables were all found to be significant at p < 0.01.</p>
<p>Experiment 3 focused on improved reliability and finding the maximum depth capabilities of the Well-Driver PUP with new weight additions added to the driving ram. Two attempts were made to determine the driving depth capabilities of the vehicle. Both well installations were conducted in Montgomery County Indiana. Water was struck at both locations. At the first location, final well depth was 2.1 m with a 0.76 m of water within the column. The driver encountered a layer of blue-gray clay that it was unable to pass through. </p>
<p>A second driving attempt was made to install a deeper well. The final well depth was 5.0 m with 1.67 m of water within the column. At this location, it is believed that a layer of limestone, shale, or siltstone was encountered. Comparing the compressive strength of limestone, sandstone, and shale, the Well-Driver PUP was not capable of driving through such materials. Therefore, at both well locations, the maximum driving depth capabilities of the driver were achieved. At both installation locations, the wells were formally developed. Both sets of water quality samples were submitted to the Montgomery County Health Department and received satisfactory ratings. </p>
<p>Experiment 4 resulted in the fabrication and design of a 4” well point. The fabricated well point was installed to create a completed well at a depth of 2.7 m in Linden IN. There was 0.1 m of water within the pipe column. The well was formally developed, and the water quality results received a satisfactory rating. A cost analysis of a 4” well by depth was conducted. The total cost to fabricate one well point totaled $661.42. Of the total cost, 81% of the costs came from the 4” base pipe and the specialty pre-perforated screen used to create the secondary screen. The completion of these experiments provides a better understanding of the driving capabilities of the Well-Driver Pup. Improving the driving depth capabilities of the Well-Driver Pup will help to push this low-cost alternative technology closer to release in the developing world.</p>
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