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Utilizing Magnets as Conductors for Power Outlet Generations
Utilizing Magnets as Conductors for Power Outlet Generations
Introduction
Introduction
The need for seamless connectivity has grown critical in many different fields as we live in a more digitally connected society. We now rely heavily on electronic devices due to the widespread purpose of this, from information processing to system control. The inability of every individual to have electronic devices available while on the go is hampered by issues that include unavailability of electricity. By giving all sorts of devices more flexibility and range, magnetized power outlets present a possible way to overcome these issues. These solutions span a variety of gadgets and technologies intended to boost the quality and increase the coverage of electronic devices in a variety of settings. Investigating the field of Magnetized Power Outlets and evaluating their usefulness, efficacy, and influence on connectivity experiences are the goals of this study. This study aims to offer alternative energy supply and provide its effectiveness that may fulfill the changing needs of users in a world that is becoming more and more mobile-centric by looking at the underlying technology, deployment techniques, and real-world applications.
The need for seamless connectivity has grown critical in many different fields as we live in a more digitally connected society. We now rely heavily on electronic devices due to the widespread purpose of this, from information processing to system control. The inability of every individual to have electronic devices available while on the go is hampered by issues that include unavailability of electricity. By giving all sorts of devices more flexibility and range, magnetized power outlets present a possible way to overcome these issues. These solutions span a variety of gadgets and technologies intended to boost the quality and increase the coverage of electronic devices in a variety of settings. Investigating the field of Magnetized Power Outlets and evaluating their usefulness, efficacy, and influence on connectivity experiences are the goals of this study. This study aims to offer alternative energy supply and provide its effectiveness that may fulfill the changing needs of users in a world that is becoming more and more mobile-centric by looking at the underlying technology, deployment techniques, and real-world applications.
Statement of the Problem
Statement of the Problem
This study aims to determine the factors needed to create a Magnetized Power Outlet hence, answering the following questions:
How much voltage does the outlet provide?
How long does the utilized power outlet last?
How efficient is the power outlet?
What are the limitations of the magnetic power outlet?
Methods
Methods
The researchers used a quasi experimental research method, according to (Cook & Campbell, 1979) quasi experimental research method is a research that resembles experimental research but not a true experimental research. Although the independent variable is manipulated, participants are not randomly assigned to conditions or orders of conditions. The independent variable is manipulated before the dependent variable is measured, as it eliminates the directionality problem. (Cook & Campbell, 1979). The researchers have gathered information about magnets, electricity, and theories that will support and make our final output successful. Upon gathering data about magnets, the researchers have looked for the materials that can be used in creating the output.
Results and Discussion
Results and Discussion
Upon completion of several tests of the magnetized power outlet, the product has proved that magnets can act as conductors in producing electricity. The first test showed that it can produce up to 220 volts of electricity
Furthermore, upon testing the product–it has produced 3 volts; with the use of a transformer and a small dynamo–however, the said materials are not connected into the outlet itself as it only acts as a support for the magnets to spin continuously causing it to produce 3 volts of electricity. However, the second test has failed to produce any voltage due to the usage of the wrong size for the pipe and dynamo.
Upon gathering and analyzing the data collected, the researchers have concluded that utilizing magnets as conductors can provide an alternative source of electricity. The product has shown its worth and capabilities by producing 3 volts of electricity despite the fact that the product needs a lot of improvement and more trials. Nevertheless, the alternative hypothesis is the result of this experiment.
References
References
Websites:
Encyclopædia Britannica, inc. (2024, February 1). Electric generator. Encyclopædia Britannica. https://www.britannica.com/technology/electric-generator
Admin. (2023, February 24). Faraday’s laws of electromagnetic induction - Lenz’s law, formula, derivation, video, and faqs. BYJUS. https://byjus.com/physics/faradays-law/?fbclid=IwAR2bc5-EOGC6Vbi5k8v0JBjHa2yYfPqmNYmn8dG8d46yyoYMa0HZhVnfS5k
Government of Canada, S. C. (2021a, September 2). 3.2 sampling 3.2.3 non-probability sampling. 3.2.3 Non-probability sampling. https://www150.statcan.gc.ca/n1/edu/power-pouvoir/ch13/nonprob/5214898-eng.htm
Admin. (2023, February 24). Faraday’s laws of electromagnetic induction - Lenz’s law, formula, derivation, video, and faqs. BYJUS. https://byjus.com/physics/faradays-law/
Journals:
Du, Sijun & Chan, Edward & Wen, Bing & Hong, John & Widmer, Hanspeter & Wheatley, Chuck. (2017). Wireless Power Transfer Using Oscillating Magnets. IEEE Transactions on Industrial Electronics. PP. 1-1. 10.1109/TIE.2017.2786289.
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