The Contribution of Geomagnetic Forces to the Lifting Force of Various Aircrafts: From Balloons and Airplanes to Flying Discs
Issue:
Volume 10, Issue 1, June 2022
Pages:
1-8
Received:
2 February 2022
Accepted:
18 February 2022
Published:
25 February 2022
Abstract: The fact that Bernoulli's principle does not explain the lift of the aircraft is finally recognized. At the same time, it is recognized that the nature of the forces that create the lifting force of aircraft is still unknown, in any case – for the representatives of official science. Correspondingly, the unacceptability of this state of affairs arouses the desire and provides an opportunity to resume discussion on the nature of the forces that provide the ability to fly both aircraft and other flying objects, including unidentified. Therefore, the analysis of forces, both electromagnetic and mechanical, involved in the creation of the lifting force can be useful. So, it is shown here that the mechanical component of lifting force of various objects flying in the atmosphere proposed here may be relevant. Thus, due to the analysis conducted here, it is shown that the same forces are able to cause flights of such dissimilar objects as balloons, airplanes and various flying disks, including Searl’s mysterious disk. As a result, special attention is drawn here to the earth’s electromagnetism, whose participation in the creation of the lifting force of various aircraft is not even suspected. As an additional result, clear explanations of the effects of both Biefeld-Brown and Hutchinson effects can be offered. Be that as it may, the discussion offered here may be at least informative.
Abstract: The fact that Bernoulli's principle does not explain the lift of the aircraft is finally recognized. At the same time, it is recognized that the nature of the forces that create the lifting force of aircraft is still unknown, in any case – for the representatives of official science. Correspondingly, the unacceptability of this state of affairs aro...
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Optimization of a Magnetic Drive Blender Orthogonal Experiment Method and Experimental Verification
Issue:
Volume 10, Issue 1, June 2022
Pages:
9-15
Received:
8 October 2022
Accepted:
2 November 2022
Published:
11 November 2022
Abstract: In order to solve the problems of the traditional blenders, such as short service life, easy leakage and high noise, a magnetic driven blender with disc magnetic coupler as the core stirring component was designed. The experimental design was carried out by orthogonal test method. The three-dimensional software Solidworks was used to establish the structural model of the disk magnetic coupler with nine groups of different structural parameters. The finite element software Ansys Maxwell was used to carry out numerical simulation of nine groups of different structural models of the disk magnetic coupler. The range analysis method was used to study the main and insignificant factors that affect the performance of the disc magnetic coupler, and the optimal structure parameters of the disc magnetic coupler were obtained. The results show that the level values with the most significant among all factors were the permanent magnet thickness (A3), the number of magnetic poles (B3), and the air gap spacing (C1), respectively. The optimal geometric parameter structure of the disk magnetic coupler was A3=10mm, B3=12 pairs, and C1=3mm, respectively. The performance of the optimized disk magnetic coupler was improved by 88%. It provides a design reference for the following research on the performance optimization of disc magnetic coupler.
Abstract: In order to solve the problems of the traditional blenders, such as short service life, easy leakage and high noise, a magnetic driven blender with disc magnetic coupler as the core stirring component was designed. The experimental design was carried out by orthogonal test method. The three-dimensional software Solidworks was used to establish the ...
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