Matching Items (188)
Description
This Honors thesis is analyzing the Jaipur Prosthetic Foot; we are using a foot from Bhagwan Mahaveer Viklang Sahayata Samiti (BMVSS) to test the durability of the foot and where the critical fatigue points are located. Our testing design will be based off of computer simulation to point out the critical points that the test machinery should accentuate. The machine will be set to sample and save data at interval times throughout the accentuated walking cycle in order to record the point where the foot begins to show wear.
ContributorsChaisson, Nathaniel (Co-author) / Jacobs, Ian (Co-author) / Radda, Nicholas (Co-author) / Henderson, Mark (Thesis director) / Sodemann, Angela (Committee member) / Carberry, Adam (Committee member) / Barrett, The Honors College (Contributor)
Created2015-05
Description
This project is a web development effort to improve the web presence of GlobalResolve. Established in 2006, GlobalResolve has directly improved the lives of underprivileged people locally and in underdeveloped nations throughout the world. This social entrepreneurship program at Arizona State University has enhanced the educational experience of students and faculty by involving them in real world projects that have shown direct results. The initiative goes beyond the traditional model of philanthropy but works to establish successful business ventures of solutions to provide sustainable economic development to the underserved communities they work with. GlobalResolve: A Digital Story is a website that was proposed to help improve the current GlobalResolve website and make a more compelling presentation of the program in hopes of attracting new funding for new projects and also student to be involved as problem solvers. The problems seen in the current website are: lack of student testimonials, sense of up keeping, context in the use of multimedia, and best web design practices. The resulting objectives for the new site were: build a product that would assist in publicizing the GlobalResolve program and tell its story to future students and prospects and potential donors. The new website solved these issues by: incorporating student experiences, embedding social media widgets regarding current projects, details of multimedia elements to provide context, and researching and implementing best design practices. The new website was developed to be an interactive experience, delivering the story of the initiative from its beginnings to it current state. The information is presented on a website with data maps, digital timelines, and short video clips, to give a thorough, interesting, and an explanation of GlobalResolve. With the incorporation of photos and graphics to assist, the website was designed to tell a compelling, composing informative yet engaging digital media. This was confirmed by doing a beta test of the website. This project evolved in many ways as an effective ways of relating information. Ultimately, the goal of this thesis was to make a digital case statement for the initiative, in order to create a clear message to prospects and potential donors. The case statement represents GlobalResolve's digital needs and how those needs can be achieved. Using digital tools and marketing, the website was approached as a strategic business plan and meant to deliver a more effective representation of the program, while setting up a template to be used for future use to allow updates that can show the progressive success of GlobalResolve.
ContributorsLopez, Carolina (Co-author) / Jeong, Yihyun (Co-author) / Henderson, Mark (Thesis director) / Reilley, Michael (Committee member) / Barrett, The Honors College (Contributor) / Walter Cronkite School of Journalism and Mass Communication (Contributor)
Created2015-12
Description
I. Executive Summary Projectors are used in more and more live and corporate events and theatrical productions. In these environments, they are subject to a myriad of conditions. These can include extreme temperatures, atmospheric effects and contaminates, shipping and rough handling, and power issues. The goal is to find ways to extend the reliable and economical lifespan of these machines increasing companies ROI and decreasing environmental damage from more frequent production, repair and disposal. The first area studied was the effect removing the covers has on the projector performance. This is important knowledge for both the research protocols followed in this research and in normal use during maintenance and repair. Testing demonstrated that the removal of covers on small consumer projectors has a profound impact on internal temperatures and can even cause overheating due to the covers being used as air ducting. The main focus of this project was finding effective pre-filters for use around haze, fog and other airborne contaminates. This was successful with two material being demonstrated to be cost effective, filter far superior to factory filters alone, and produce acceptable impacts on projector cooling in several models and types of projector. These filters cost typically less than $1 per filter and reduce the ingress of contaminates by 60-80%. Additionally the effects of improper shutdown versus the manufacturers specified shutdown process were tested. It was determined that the projectors where power was unplugged or turned off had components exceed both operating temperatures and temperatures during the normal shutdown. This shows that following the correct shutdown process keeps components cooler leading to a longer component life and therefore longer projector life and decreased repairs.
ContributorsBooth, Kelsey (Author) / Henderson, Mark (Thesis director) / Pinholster, Jacob (Committee member) / Gaddy, Davin (Committee member) / Barrett, The Honors College (Contributor)
Created2014-05
Description
Access to clean water is an issue that abounds in many areas across the world. It is estimated that over 770 million people lack access to improved sources of water. However, the lack of access to clean water does not just affect people's health; it is a problem that affects three major areas. Because people do not have clean drinking water, millions of school days are missed per year due to water-related disease or children being forced to procure clean water. Also, gender inequalities result from women bearing the majority of the responsibility of walking long distances to find a source of potable water. Therefore, lack of access to clean water affects people's health, their education, and gender equality. The problem is not that there is a lack of technologies to provide clean water; the problem is that these technologies are not being implemented sustainably in the areas that need them most. To bring better access of clean water to people in developing nations, 33 Buckets has designed a distribution platform that uses schools as the central point for water distribution to local communities. A sustainable filtration system will be installed at the school to provide clean water for the people at the school. People in the nearby community will also be able to get free water if they bring their own containers to the school. To maintain the filter and provide it with any repairs that are necessary, water will be sold to nearby businesses lower than the current market prices. These profits will be used to ensure the quality of the filtration system and also to provide educational improvements to the school. An advisory committee made up of men and women will be assembled to run the filtration business and handle the finances. A pilot project to implement this model has been identified as the Rahima Hoque Girls School in rural Bangladesh. The team will travel to Bangladesh in Summer 2014 to install a filter at the school, purchase water testing supplies and containers, and meet with the advisory committee to go over final logistical details. Financial projections show that if the filter operates at 50% of its expected frequency and water is sold 5 days a week for 52 weeks, the school will generate $33,532.31. These profits are more than enough to maintain the system and pay for educational improvements to the school. Once implementation of the site is completed, the project will be monitored to track how the water selling business is operating. If the model is shown to be successful, it can then be scaled to other nearby schools or other countries with water contamination problems.
ContributorsWiegand, Connor James (Author) / Henderson, Mark (Thesis director) / Shrake, Scott (Committee member) / Barrett, The Honors College (Contributor) / Harrington Bioengineering Program (Contributor)
Created2014-05
Description
The global energy demand is expected to grow significantly in the next several decades and support for energy generation with high carbon emissions is continuing to decline. Alternative methods have gained interest, and wind energy has established itself as a viable source. Standard wind farms have limited room for growth and improvement, so wind energy has started to explore different directions. The urban environment is a potential direction for wind energy due to its proximity to the bulk of energy demand. CFD analysis has demonstrated that the presence of buildings can accelerate wind speeds between buildings and on rooftops. However, buildings generate areas of increased turbulence at their surface. The turbulence thickness and intensity vary with roof shape, building height, and building orientation. The analysis has concluded that good wind resource is possible in the urban environment in specific locations. With that, turbine selection becomes very important. A comparison has concluded that vertical axis wind turbines are more useful in the urban environment than horizontal axis wind turbines. Furthermore, building-augmented wind turbines are recommended because they are architecturally integrated into a building for the specific purpose of generating more energy. The research has concluded that large-scale generation in the urban environment is unlikely to be successful, but small-scale generation is quite viable. Continued research and investigation on urban wind energy is recommended.
ContributorsKlumpers, Ryan Scott (Author) / Calhoun, Ronald (Thesis director) / Huang, Huei-Ping (Committee member) / Barrett, The Honors College (Contributor) / Mechanical and Aerospace Engineering Program (Contributor)
Created2014-05
Description
The paper presents a new exhaust header design to replace the current design on Arizona State University's Formula SAE car. Also, the thought process of the design was presented as well as a method of analysis for tuning the exhaust headers. The equation presented was then compared with a computational fluid dynamics model using ANSYS Fluent. It was found that the equation did not match the timing of the CFD model. However, the design does allow for simple changes to be made in order to reduce the length of the exhaust and allow for the correct tuning. Also, the design minimizes interference between the individual headers which is ideal to increase engine performance. The exhaust meets the Formula SAE regulations, and is designed to fit in the new chassis for the FSAE car that ASU will run in 2015. Recommendations were also made to further improve the design and analysis model.
ContributorsKaashoek, Kevin Jason (Author) / Huang, Huei-Ping (Thesis director) / Trimble, Steven (Committee member) / Barrett, The Honors College (Contributor) / Mechanical and Aerospace Engineering Program (Contributor)
Created2014-05
Description
Bangladesh is facing one of the largest mass poisonings in human history with over 77 million people affected by contaminated water each and every day. Over the last few years, the 33 Buckets team has come together to help fulfill this clean water need through filtration, education, and an innovative distribution system to inspire and empower people in Bangladesh and across the world. To start this process, we are working with the Rahima Hoque Girls' school in the rural area of Raipura, Bangladesh to give girls access to clean water where they spend the most time. Through our assessment trip in May 2012, we were able to acquire technical data, community input, and partnerships necessary to move our project forward. Additionally, we realized that in many cases, including the Rahima Hoque school, water problems are not caused by a lack of technology, but rather a lack of utilization and maintenance long-term. To remedy this, 33 Buckets has identified a local filter to have installed at the school, and has designed a small-scale business focused on selling clean water in bulk to the surrounding community. Our price point and association with the Rahima Hoque Girls' school makes our solution sustainable. Plus, with the success of our first site, we see the potential to scale. We already have five nearby schools interested in working to implement similar water projects, and with over 100,000 schools in Bangladesh, many of which lack access to the right water systems, we have a huge opportunity to impact millions of lives. This thesis project describes our journey through this process. First, an introduction to our work prior to the assessment trip and through the ASU EPICS program is given. Second, we include quantitative and qualitative details regarding our May 2012 assessment trip to the Rahima Hoque school and Dhaka. Third, we recount some of the experiences we were able to participate in following the trip to Bangladesh, including the Dell Social Innovation Challenge. Fourth, we examine the technical filtration methods, business model development, and educational materials that will be used to implement our solution this summer. Finally, we include an Appendix with a variety of social venture competitions and applications that we have submitted over the past two years, in addition to other supplementary materials. These are excellent examples of our diligence and provide unique insight into the growth of our project.
ContributorsStrong, Paul Andrew (Co-author) / Shah, Pankti (Co-author) / Huerta, Mark (Co-author) / Henderson, Mark (Thesis director) / El Asmar, Mounir (Committee member) / LaBelle, Jeffrey (Committee member) / Barrett, The Honors College (Contributor) / Mechanical and Aerospace Engineering Program (Contributor)
Created2013-05
Description
"Seventy five percent of the world's poor live in rural areas of developing countries, where most people's livelihoods rely directly on agriculture." (USAid, 2014) Reduced levels of crop production and the accompanying problems of malnourishment exist all over the world. In rural Peru, for example, 11 percent of the population is malnourished. (Global Healthfacts.org, 2012) Since the success in agriculture relies importantly on the fertility of the soil, it is imperative that any efforts at reversing this trend be primarily directed at improving the existing soils. This, in turn, will increase crop yields, and if done properly, will also conserve natural resources and maximize profits for farmers. In order to improve the lives of those at the bottom of the pyramid through agriculture, certain tools and knowledge must be provided in order to empower such persons to help themselves. An ancient method of soil improvement, known as Terra Preta do Indio (Indian dark earth), was discovered by Anthropologists in the 1800's. These dark, carbon-rich, soils are notable for their high fertility, high amounts of plant available nutrients, and their high moisture retention rates. The key to their long-lasting fertility and durability is the presence of high levels of biochar, a highly stable organic carbon \u2014 produced when organic matter (crop residues, food waste, manure, etc.) is burned at low temperatures in the absence of oxygen. Research has shown that when charcoal (biochar) and fertilizers are combined, it can yield as much as 880 percent more than when fertilizers are used by themselves. (Steiner, University of Bayreuth, 2004)
ContributorsStefanik, Kathleen Ann (Author) / Henderson, Mark (Thesis director) / Johnson, Nathan (Committee member) / Barrett, The Honors College (Contributor) / Human Systems Engineering (Contributor)
Created2014-12
Description
This study examines the impact of spatial landscape configuration (e.g., clustered, dispersed) on land-surface temperatures (LST) over Phoenix, Arizona, and Las Vegas, Nevada, USA. We classified detailed land-cover types via object-based image analysis (OBIA) using Geoeye-1 at 3-m resolution (Las Vegas) and QuickBird at 2.4-m resolution (Phoenix). Spatial autocorrelation (local Moran’s I ) was then used to test for spatial dependence and to determine how clustered or dispersed points were arranged. Next, we used Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) data acquired over Phoenix (daytime on 10 June and nighttime on 17 October 2011) and Las Vegas (daytime on 6 July and nighttime on 27 August 2005) to examine day- and nighttime LST with regard to the spatial arrangement of anthropogenic and vegetation features. Local Moran’s I values of each land-cover type were spatially correlated to surface temperature. The spatial configuration of grass and trees shows strong negative correlations with LST, implying that clustered vegetation lowers surface temperatures more effectively. In contrast, clustered spatial arrangements of anthropogenic land-cover types, especially impervious surfaces and open soil, elevate LST. These findings suggest that city planners and managers should, where possible, incorporate clustered grass and trees to disperse unmanaged soil and paved surfaces, and fill open unmanaged soil with vegetation. Our findings are in line with national efforts to augment and strengthen green infrastructure, complete streets, parking management, and transit-oriented development practices, and reduce sprawling, unwalkable housing development.
ContributorsMyint, Soe Win (Author) / Zheng, Baojuan (Author) / Talen, Emily (Author) / Fan, Chao (Author) / Kaplan, Shari (Author) / Middel, Ariane (Author) / Smith, Martin (Author) / Huang, Huei-Ping (Author) / Brazel, Anthony J. (Author)
Created2015-06-29
Description
Thermal modeling and investigation into heat extraction methods for building-applied photovoltaic (BAPV) systems have become important for the industry in order to predict energy production and lower the cost per kilowatt-hour (kWh) of generating electricity from these types of systems. High operating temperatures have a direct impact on the performance of BAPV systems and can reduce power output by as much as 10 to 20%. The traditional method of minimizing the operating temperature of BAPV modules has been to include a suitable air gap for ventilation between the rooftop and the modules. There has been research done at Arizona State University (ASU) which investigates the optimum air gap spacing on sufficiently spaced (2-6 inch vertical; 2-inch lateral) modules of four columns. However, the thermal modeling of a large continuous array (with multiple modules of the same type and size and at the same air gap) had yet to be done at ASU prior to this project. In addition to the air gap effect analysis, the industry is exploring different ways of extracting the heat from PV modules including hybrid photovoltaic-thermal systems (PV/T). The goal of this project was to develop a thermal model for a small residential BAPV array consisting of 12 identical polycrystalline silicon modules at an air gap of 2.5 inches from the rooftop. The thermal model coefficients are empirically derived from a simulated field test setup at ASU and are presented in this thesis. Additionally, this project investigates the effects of cooling the array with a 40-Watt exhaust fan. The fan had negligible effect on power output or efficiency for this 2.5-inch air gap array, but provided slightly lower temperatures and better temperature uniformity across the array.
ContributorsHrica, Jonathan Kyler (Author) / Tamizhmani, Govindasamy (Thesis advisor) / Rogers, Bradley (Committee member) / Macia, Narciso (Committee member) / Arizona State University (Publisher)
Created2010