Buoyancy-resulting force point-moving perpetual motion machine

Abstract

This invention provides a perpetual motion machine that utilizes buoyancy based on Archimedes' principle and other principles. [Solution] In a liquid, the pressure of the liquid is high at greater depths and low at shallower depths. By utilizing this difference in pressure, a method has been discovered to arbitrarily move the point of application of the resultant buoyancy force, while the resultant buoyancy force remains the same. This device is characterized by arbitrarily moving the point of application of the resultant buoyancy force, thereby creating a difference in the distance from the central axis, and converting the difference in moment force due to this difference in distance into rotational kinetic energy.

Description

【Technical Field】 【0001】 The present invention relates to a perpetual machine that utilizes buoyancy on an object in a liquid. 【Background Art】 【0002】 Since ancient times, there have been many concepts and experiments on perpetual machines that utilize buoyancy. These concepts and experiments can be broadly classified into the following two points. 1. Increase or decrease the volume of the main buoyancy individual part using a weight or the like. Obtain rotational kinetic energy by comparing the volume = buoyancy. 2. Without changing the volume of the main buoyancy individual part, force it to move using a guide or the like to create a difference in the distance from the central rotation axis. Obtain rotational kinetic energy from the difference in the buoyancy moment force. energy. However, these devices never moved even for a moment. 【Prior Art Documents】 【Patent Documents】 【0003】 【Patent Document 1】 Japanese Patent Application No. 2023-17172 【Patent Document 2】 Japanese Patent Application No. 2023-11367 【Non-Patent Documents】 【0004】 【Non-Patent Document 1】 【Summary of the Invention】 【Problems to be Solved by the Invention】 【0005】 The concepts and experiments in the basic principles of perpetual machines that utilize buoyancy up to now have been described in the background art section as well, and can be broadly classified into the following two types. 1. Increase or decrease the volume of the main buoyancy individual part using a weight or the like. Obtain rotational kinetic energy by comparing the volume = buoyancy. 2. The volume of the main buoyancy-generating solid part remains unchanged, but it is forcibly moved using guides or the like to create a difference in its distance from the central axis of rotation. Rotational kinetic energy is obtained from the difference in buoyancy moment force. However, these concepts and experimental devices never worked even for a single moment, and numerous concepts and experiments ended in failure. The following reasons can be considered for the failure of these concepts and experiments. 【0006】 The device, broadly categorized as "1. Increasing or decreasing the volume of the main buoyancy solid part using weights, etc.," requires weights heavier than the liquid pressure. Furthermore, when attempting to rotate the axis of rotation, the moment of the weights acts in the opposite direction to the rotation, thus failing to achieve the intended results. 【0007】 In the case of the device described as "2. The volume of the main buoyancy solid part does not change, but it is forcibly moved using guides, etc., to create a difference in distance from the central rotation axis," energy loss occurred because the main buoyancy solid part was forcibly moved using guides, etc., and the intended results could not be obtained. These numerous failures would eventually lead to the discovery of the first and second laws of thermodynamics. 【0008】 This time, drawing on numerous failures, we overcame those challenges using a new method (bound only by known natural laws, which can be understood with knowledge at the level of middle school physics) and succeeded in developing a perpetual motion machine that can obtain rotational kinetic energy indefinitely. Although this device is a perpetual motion machine, as mentioned above, it utilizes known natural laws, and therefore falls under Article 2 (Definitions), Paragraph 1 of the Patent Act, and does not violate Article 32 (Inventions that cannot be patented) of the same Act. [Means for solving the problem] 【0009】 To solve the above problems, the resultant force of buoyancy on the left and right sides of the vertical axis around the central rotation axis is the same, but the position (distance) of the point of application of the resultant force of buoyancy from the central axis is different. This difference in the distance of the point of application of the resultant force of buoyancy from the central axis falls into category 2 of the above classification of perpetual motion machines based on buoyancy. However, instead of forcibly moving the position of the point of application of the resultant force of buoyancy using a guide, the movement of its position is made possible by the pressure of the liquid. In other words, the pressure of the liquid causes a shift in the position of the point of application of the resultant buoyancy force, which creates a difference in the moment force due to buoyancy on the left and right sides of the vertical line passing through the central axis of rotation (sum of buoyancy × distance from the central axis to the point of application of the sum of buoyancy forces), making it possible to rotate the central axis of rotation. This indicates that if the state of the left and right sides of the central rotation axis is reversed, the point of application of the resultant buoyancy force will shift again due to the pressure of the liquid, creating a difference in the moment force with respect to the central rotation axis, and causing rotation around the central axis. By endlessly repeating these actions, this device becomes a perpetual motion machine utilizing buoyancy. The following describes the specific means of this device. 【0010】 Buoyancy generation section 10 = A section that changes the point of application of the resultant buoyancy force due to the pressure of the liquid. As the buoyancy generating unit 10, A buoyancy body extension / retractable movable body connecting plate 14 is attached to one face and the other opposite face of the buoyancy body 11, which is a rectangular parallelepiped with a hollow interior and airtightness that prevents liquid from entering from the outside to the interior, and to both faces, with the plate being slightly larger than the face and the other opposite face of the buoyancy body 11, and having guide frame holes 16 in the larger portion. One end of a retractable movable body (central axis side) 12, which is a rectangular parallelepiped with a hollow interior and airtightness, and easily expandable, is attached to one side of a buoyancy body retractable movable body connecting plate 14 attached to the buoyancy body 11, on the side not facing the buoyancy body 11. The retractable movable body has an area half the size of the surface area of ​​the buoyancy body 11. On the side of the connecting plate 14 for other buoyancy bodies that is attached to the buoyancy body 11, not the side facing the buoyancy body 11, is attached one end of a rectangular parallelepiped (outer frame side) 13, which has the same surface area as the telescopic movable body (central axis side) 12, is hollow inside, airtight, and easily expandable and contract. The attachment positions of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 to the buoyancy body telescopic movable body connecting plate 14 are the same as the positions of the upper and lower halves of the connection surface of the buoyancy body 11 sandwiched between the two buoyancy body telescopic movable body connecting plates 14. In other words, the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are positioned so that they do not overlap even if they are virtually extended toward the buoyancy body 11. Furthermore, the extension and retraction directions of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are limited to the direction of the surface of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 attached to the buoyancy body telescopic movable body connecting plate 14, and the direction of the surface opposite to that surface. A gas inlet / outlet hole 15 is provided on the connection surface between the retractable movable body (central axis side) 12 and the buoyancy body retractable movable body connecting plate 14. In addition, a gas inlet / outlet hole 15 is provided on the connection surface between the buoyancy body retractable movable body connecting plate 14 and the buoyancy body 11 at the same position as the gas inlet / outlet hole 15 provided on the connection surface between the retractable movable body (central axis side) 12 and the buoyancy body retractable movable body connecting plate 14. A gas inlet / outlet hole 15 is provided on the connection surface between the retractable movable body (outer frame side) 13 and the buoyancy body retractable movable body connecting plate 14. In addition, a gas inlet / outlet hole 15 is provided on the connection surface between the buoyancy body retractable movable body connecting plate 14 and the buoyancy body 11 at the same position as the gas inlet / outlet hole 15 provided on the connection surface between the retractable movable body (outer frame side) 13 and the buoyancy body retractable movable body connecting plate 14. 【0011】 Rotation drive unit 20 = Part that obtains a difference in moment force due to the difference in the point of application of the resultant force of buoyancy. As the rotary drive unit 20, The rotary drive unit 20 has a central shaft 24 that is hollow inside and airtight, preventing liquid from entering from the outside. An equal number of guide frames 22, each with the same length and diameter, are attached to the center of the central shaft 24, which is the core of the rotary drive unit 20. A connecting plate 23 for the outer frame of each extendable and movable body is attached to the other end of each of the multiple guide frames 22. The outer frame 21 is attached to each extendable movable outer frame connecting plate 23. 【0012】 The body part 30 is the part that constantly supports this device. As the body part 30, Attach the support column 32 to the base 33, which serves as the foundation of the support part during the operation of this device. Attach the rotating shaft 31 to the support column 32 so that the rotation of the rotation driving part of this device can be performed smoothly. 【0013】 The configurations of the above-mentioned buoyancy generating part 10, rotation driving part 20, and body part 30 are as follows. In order for each buoyancy body 11 to move only along each guide frame 22, insert each of the plurality of guide frames 22 into the plurality of guide frame holes 16 of the buoyancy body telescopic movable body connection plate 14 attached to each buoyancy body 11. The other end of the telescopic movable body (central axis side) 12 attached to the buoyancy body telescopic movable body connection plate 14 is attached to each surface of the central axis 24, and the other end of the telescopic movable body (outer peripheral frame side) 13 attached to the buoyancy body telescopic movable body connection plate 14 is attached to the telescopic movable body outer peripheral frame connection plate 23 respectively. When attaching each telescopic movable body (central axis side) 12 to the central axis 24, attach it at the same position on the surface of the central axis 24 as seen from the center of the central axis 24 (if it is the left side as seen from the center of the central axis 24, it is the left side on all surfaces, and if it is the right side, it is the right side on all surfaces). The positions where each telescopic movable body (central axis side) 12 is attached are the same as seen from the center of the central axis 2如上所述. Therefore, when attaching each telescopic movable body (outer peripheral frame side) 13 to the buoyancy body telescopic movable body connection plate 14, since it is staggered with the telescopic movable body (central axis side) Provide gas inlet / outlet holes 25 at the attachment parts of the telescopic movable body (central axis side) 12 and each surface of the central axis 24. Attach the central axis 24 to the rotating shaft 31. With the above means and configurations, this device becomes a perpetual motion machine that utilizes buoyancy. 【Effects of the Invention】 【0014】 Next, the effects on this device, the buoyancy perpetual motion machine, by adopting the configuration described in the section on means for solving the problem will be explained using Figures 3-1 and 3-2, etc. 【0015】 The main parts of this device that are subjected to liquid pressure while submerged in liquid As shown in Figures 3-1 and 3-2, the buoyancy body telescopic movable body connecting plates 14 attached to both sides of the buoyancy body 11 have the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 attached to them. Therefore, the main part of this device that receives the liquid pressure when it is submerged in liquid is the side of the buoyancy body telescopic movable body connecting plate 14 that is not on the buoyancy body 11 side, opposite to the part to which the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are attached. In other words, the main part of this device that receives the liquid pressure is the side of each buoyancy body telescopic movable body connecting plate 14 that does not have the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 attached. Furthermore, as described above, the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are not attached in a straight line but are attached at different heights. Therefore, even if the attached telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are virtually extended toward the buoyancy body telescopic movable body connection plate 14, they will not overlap with each other. Although the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 attempt to contract due to the pressure of the liquid, the other ends of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are attached and fixed to each surface of the central axis 24 and to each telescopic movable body outer frame connecting plate 23. Therefore, the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 contract only on the buoyancy body 11 side, and the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 on the central axis 24 and the telescopic movable body outer frame connecting plate 23 side are not affected by the pressure of the liquid. Therefore, in this device, which is submerged in liquid, when the liquid pressure is applied to the connection surfaces of the buoyancy body telescopic movable body connecting plate 14, specifically the connection surfaces of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13, the two surfaces of the buoyancy body telescopic movable body connecting plate 14 attached to the buoyancy body 11 will be compared. The telescopic movable body (central axis side) 12 or the telescopic movable body (outer frame side) 13 attached to the side with greater pressure will expand, while the telescopic movable body (central axis side) 12 or the telescopic movable body (outer frame side) 13 attached to the side with less pressure will contract. Due to these contraction and expansion actions, the buoyancy body 11 attached between the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 will move along the guide frame 22 between the central axis 24 and the telescopic movable body outer frame connecting plate 23. 【0016】 It was found that the main parts of this device that are subjected to liquid pressure while submerged in liquid are the surfaces of the buoyancy body extension / retraction connecting plates 14 attached to both sides of the buoyancy body 11, excluding the extension / retraction movable body (central axis side) 12 and the extension / retraction movable body (outer frame side) 13. Based on this, the following two points can be considered as elements that are subjected to liquid pressure in this device while submerged in liquid. 1. The ratio of the surface area of ​​the surface subjected to pressure. 2. The depth of the pressure-bearing surface in the liquid. Although the surface area of ​​the buoyancy body telescopic movable body connecting plates 14 attached to both sides of the buoyancy body 11 is the same except for the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13, the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are attached at different heights. Therefore, when the device rotates around the central axis 24, there are only two places (areas A and C in Figures 3-1 and 3-2) where the depth is the same. 【0017】 Figure 3-1: Area A The portion consisting of the retractable movable body (central axis side) 12, the buoyancy body retractable movable body connecting plate 14, the buoyancy body 11, the buoyancy body retractable movable body connecting plate 14, and the retractable movable body (outer frame side) 13 is located in the vertical and horizontal directions. In this case, the relationship between the positions of the surfaces of the expandable / contractible body (central axis side) 12 and the expandable / contractible body (outer frame side) 13 that receive liquid pressure is as follows: Vertical orientation: Expandable / contractible body (central axis side) 12 = deep in liquid Extendable movable body (outer frame side) 13 = shallow depth in liquid Horizontal orientation: Expandable / contractible body (central axis side) 12 = shallow depth in liquid Extendable movable body (outer frame side) 13 = deep in liquid This relationship results in a reversal of the depth in the liquid during movement from the vertical to the horizontal direction. Figure 3-2: Area A Therefore, as the part consisting of the telescopic movable body (central axis side) 12, the buoyancy body telescopic movable body connecting plate 14, the buoyancy body 11, the buoyancy body telescopic movable body connecting plate 14, and the telescopic movable body (outer frame side) 13 moves from the vertical to the horizontal direction, the contraction of the telescopic movable body (outer frame side) 13, which is at a deeper depth in the liquid, outweighs the contraction of the telescopic movable body (central axis side) 12, causing the buoyancy body 11 to move toward the outer frame 21. 【0018】 Figure 3-1: Area B, Figure 3-2: Area B Figure 3-1: In the area B, the part consisting of the expandable / contractable body (central axis side) 12, the buoyancy body expandable / contractable body connecting plate 14, the buoyancy body 11, the buoyancy body expandable / contractable body connecting plate 14, and the expandable / contractable body (outer frame side) 13 always has a shallow submersion depth in the liquid, and in the intermediate zone between the horizontal and vertical directions in Figure 3-2: Area B, the submersion depth of the expandable / contractable body (central axis side) 12 is always shallow, while the submersion depth of the expandable / contractable body (outer frame side) 13 is deep. Therefore, the buoyancy body 11 maintains its position on the outer frame 21 side. 【0019】 Figure 3-1: Region C The relationship between the positions of the surfaces of the expandable / contractible body (central axis side) 12 and the expandable / contractible body (outer frame side) 13 that receive liquid pressure in this region is as follows: Vertical orientation: Expandable / contractible body (central axis side) 12 = shallow depth in liquid Extendable movable body (outer frame side) 13 = deep in liquid Horizontal direction: Expandable / contractible body (central axis side) 12 = deep in liquid Extendable movable body (outer frame side) 13 = shallow depth in liquid This relationship is the opposite of the relationship in region A in Figures 3-1 and 3-2. Figure 3-2: Region C Therefore, as the part consisting of the telescopic movable body (central axis side) 12, the buoyancy body telescopic movable body connecting plate 14, the buoyancy body 11, the buoyancy body telescopic movable body connecting plate 14, and the telescopic movable body (outer frame side) 13 moves from the vertical to the horizontal direction, the contraction of the telescopic movable body (central axis side) 12, which is in deeper liquid depth, outweighs the contraction of the telescopic movable body (outer frame side) 13, causing the buoyancy body 11 to move toward the central axis 24. 【0020】 Figure 3-1: Region D, Figure 3-2: Region D Figure 3-1: In the D region, the part consisting of the expandable / contractable body (central axis side) 12, the buoyancy body expandable / contractable body connecting plate 14, the buoyancy body 11, the buoyancy body expandable / contractable body connecting plate 14, and the expandable / contractable body (outer frame side) 13 always has a deep submersion depth for the expandable / contractable body (central axis side) 12 and a shallow submersion depth for the expandable / contractable body (outer frame side) 13 in the horizontal and vertical directions, and in the intermediate zone between the horizontal and vertical directions in Figure 3-2: D region. Therefore, the buoyancy body 11 maintains its position on the side of the central axis 24. 【0021】 In other words, Figure 3-1: Area D, Area A (vertical direction) ⇒ Figure 3-2: Area A ⇒ Figure 3-1: Area A, Area B (horizontal direction) ⇒ Figure 3-2: Area B ⇒ Figure 3-1: Area B, Area C (vertical direction) ⇒ Figure 3-2: Area C ⇒ Figure 3-1: Area C, Area D (horizontal direction) ⇒ Figure 3-2: Area D ⇒ Figure 3-1: Area D, Area A (vertical direction) The position of the buoyancy body 11 in each area is, Central axis 24 side ⇒ Move ⇒ Outer frame 21 side ⇒ Outer frame 21 side ⇒ Outer frame 21 side ⇒ Move ⇒ Central axis 24 side ⇒ Central axis 24 side ⇒ Central axis 24 side This is the result. As mentioned above, since the buoyancy body 11 moves along the guide frame 22, it does not move outside the plane of the central axis 24 and the outer frame 21. Furthermore, the gas inside the expandable / contractable movable body (central axis side) 12 and the expandable / contractable movable body (outer frame side) 13 during the movement of the buoyancy body 11 is kept constant by gas inlet / outlet holes 15 and 25, respectively, so that the internal gas does not obstruct the air pressure. 【0022】 From the above, it was found that no movement of the buoyancy body 11 occurs in the horizontal direction passing through the central axis 24, but it moves at the intermediate positions of areas A and C in Figures 3-1 and 3-2. 【0023】 This indicates that, in the A-B and C-D regions of the vertical line passing through the central axis 24 of the device, there is no change in the resultant force of the buoyancy of the telescopic movable body (central axis side) 12, the buoyancy body telescopic movable body connecting plate 14, the buoyancy body 11, the buoyancy body telescopic movable body connecting plate 14, and the telescopic movable body (outer frame side) 13, but the movement of the buoyancy body 11 causes a difference in the distance to the point of application of the resultant force of the buoyancy relative to the central axis 24. Therefore, due to the difference in buoyancy moments (distance from the central axis 24 to the point of application of the resultant buoyancy force × resultant buoyancy force (constant)) in the A-B and C-D regions of the vertical line passing through the central axis 24, this device will rotate indefinitely in the order A⇒B⇒C⇒D⇒A in the regions shown in Figures 3-1 and 3-2. [Brief explanation of the drawing] 【0024】 [Figure 1] This is a front view of the device. [Figure 2] This is a side view of the device. [Figure 3-1] This diagram shows the configuration of the buoyancy generating unit 10 in regions A, B, C, and D. [Figure 3-2] This diagram shows the configuration of the buoyancy generating unit 10 in regions A, B, C, and D. [Figure 4] These are a front view and a side view of the main body 30 of the device. [Figure 5] This is a front view of the rotary drive unit 20. [Figure 6] This is a front view of the buoyancy generating unit 10. [Figure 7] This is a location diagram of the parts shown in Figure 8 and Figure 9. [Figure 8]This is a flow diagram of the gas in section 7E. [Figure 9] This is a flow diagram of the gas in section F of Figure 7. [Figure 10] These are a front view, an overhead view, and a cross-sectional view of the buoyancy body 11. [Figure 11] Figures 3-1 and 3-2 show examples of the configuration of the buoyancy body 11 in area A. [Modes for carrying out the invention] 【0025】 The embodiments of this device will be described below based on the examples provided. 【0026】 Figures 6, 8, 9, and 10: Buoyancy generating unit 10 A buoyancy body extension / retractable movable body connecting plate 14 is attached to one face and the other opposite face of the buoyancy body 11, which is a rectangular parallelepiped with a hollow interior and airtightness that prevents liquid from entering from the outside to the interior, and to both faces, with the plate being slightly larger than the face and the other opposite face of the buoyancy body 11, and having guide frame holes 16 in the larger portion. One end of a retractable movable body (central axis side) 12, which is a rectangular parallelepiped with a hollow interior and airtight, easily expandable shape, is attached to one side of a buoyancy body retractable movable body connecting plate 14 attached to the buoyancy body 1.1, on the side not facing the buoyancy body 11. On the side of the connecting plate 14 for other buoyancy bodies that is attached to the buoyancy body 11, not the side facing the buoyancy body 11, is attached one end of a rectangular parallelepiped (outer frame side) 13, which has the same surface area as the telescopic movable body (central axis side) 12, is hollow inside, airtight, and easily expandable and contract. The attachment positions of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 to the buoyancy body telescopic movable body connecting plate 14 are the same as the positions of the upper and lower halves of the connection surface of the buoyancy body 11 sandwiched between the two buoyancy body telescopic movable body connecting plates 14. In other words, the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are positioned so that they do not overlap even if they are virtually extended toward the buoyancy body 11. Furthermore, the extension and retraction directions of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 are limited to the direction of the surface of the telescopic movable body (central axis side) 12 and the telescopic movable body (outer frame side) 13 attached to the buoyancy body telescopic movable body connecting plate 14, and the direction of the surface opposite to that surface. A gas inlet / outlet hole 15 is provided on the connection surface between the retractable movable body (central axis side) 12 and the buoyancy body retractable movable body connecting plate 14. In addition, a gas inlet / outlet hole 15 is provided on the connection surface between the buoyancy body retractable movable body connecting plate 14 and the buoyancy body 11 at the same position as the gas inlet / outlet hole 15 provided on the connection surface between the retractable movable body (central axis side) 12 and the buoyancy body retractable movable body connecting plate 14. A gas inlet / outlet hole 15 is provided on the connection surface between the retractable movable body (outer frame side) 13 and the buoyancy body retractable movable body connecting plate 14. In addition, a gas inlet / outlet hole 15 is provided on the connection surface between the buoyancy body retractable movable body connecting plate 14 and the buoyancy body 11 at the same position as the gas inlet / outlet hole 15 provided on the connection surface between the retractable movable body (outer frame side) 13 and the buoyancy body retractable movable body connecting plate 14. 【0027】 Figures 5, 8, and 9: Rotary drive unit 20 The rotary drive unit 20 has a central shaft 24 that is hollow inside and airtight, preventing liquid from entering from the outside. Multiple guide frames 22 are attached radially to each of its four sides, with the same number of ends attached to each side. The guide frames 22 are all the same in length and diameter. Each of the multiple guide frames 22 has a connecting plate 23 for the outer frame of the extendable and retractable body attached to the other end. The outer frame 21 is attached to each extendable movable outer frame connecting plate 23. 【0028】 Figure 4: Main body 30 The support column 32 is attached to the base 33, which serves as the foundation for the support portion during the operation of this device. To ensure smooth rotation of the rotary drive unit of this device, the rotating shaft 31 is attached to the support column 32. 【0029】 The configuration of the buoyancy generating unit 10, the rotation drive unit 20, and the main body unit 30 described above is as follows. To ensure that each buoyancy body 11 moves only along its respective guide frame 22, multiple guide frames 22 are inserted into multiple guide frame holes 16 of the buoyancy body telescopic movable connecting plate 14 attached to each buoyancy body 11. The other end of the telescopic movable body (central axis side) 12 attached to the buoyancy body telescopic movable body connecting plate 14 is attached to each surface of the central axis 24, and the other end of the telescopic movable body (outer frame side) 13 attached to the buoyancy body telescopic movable body connecting plate 14 is attached to the telescopic movable body outer frame connecting plate 23. When attaching each retractable movable body (on the central axis side) 12 to the central axis 24, they are attached at the same position on the surface of the central axis 24 when viewed from the center of the central axis 24 (if it is on the left side when viewed from the center of the central axis 24, it is on the left side on all surfaces; if it is on the right side, it is on the right side on all surfaces). As described above, the mounting positions of each telescopic movable body (central axis side) 12 are the same when viewed from the center of the central axis 24. Therefore, when attaching each telescopic movable body (outer frame side) 13 to each buoyancy body telescopic movable body connecting plate 14, the mounting position of each telescopic movable body (outer frame side) 13 to the telescopic movable body outer frame connecting plate 23 is automatically determined because it is offset from the telescopic movable body (central axis side) 12. Gas inlet / outlet holes 25 are provided at the mounting portions of the extendable / retractable body (central axis side) 12 and each surface of the central axis 24. The central axis 24 is attached to the rotating axis 31. With the above steps completed, the joining of the buoyancy generating unit 10 and the rotation drive unit 20, and the joining of the rotation drive unit 20 and the main body unit 30 are finished. This device is a perpetual motion machine that utilizes buoyancy, consisting of the above configuration. [Industrial applicability] 【0030】 Because this device utilizes only the pressure and buoyancy of a liquid, it is free from geographical and temporal constraints and can supply rotational kinetic energy indefinitely. For example, if you have a tank or similar container, you can place this device inside and obtain a stable rotational energy at all times. By converting this rotational kinetic energy into electrical energy, which is the most important energy source in modern society, it is expected to contribute to industrial development as a part of renewable energy. Furthermore, since it can be installed anywhere, above or below ground, it is believed that it can also be used as an energy source during major disasters. [Explanation of symbols] 【0031】 10 Buoyancy generating section 11 Buoyancy devices 12 Telescopic movable body (center axis side) 13. Extendable movable body (outer frame side) 14 Buoyancy device, telescopic and movable body connecting plate 15 Gas outlet / inlet 16 Guide frame holes 20 Rotary drive unit 21 Outer frame 22 Guide Frames 23. Extendable movable body outer frame connection plate 24 Center axis 25 Gas inlet / outlet holes 30 Body part 31 Rotation axis 32 Pillar 33. Base

Claims

[Claim 1] A buoyancy body 11 is a rectangular parallelepiped that is hollow inside and airtight, preventing liquid from entering from the outside to the inside. Each buoyancy body telescopic movable body connecting plate 14 is attached to one side and the other corresponding side of the aforementioned buoyancy body 11, and is slightly larger than the one side and the other corresponding side of the buoyancy body 11, with a guide frame hole 16 provided in the larger portion. Of the aforementioned buoyancy body 11, on the side of one of the aforementioned buoyancy body telescopic movable body connecting plates 14 that is not on the buoyancy body 11 side, at the same position as the upper or lower half of the surface of the buoyancy body 11 sandwiching the buoyancy body telescopic movable body connecting plate 14, there is a rectangular parallelepiped whose area of ​​the opposing surface is half the area of ​​the surface of the buoyancy body 11 sandwiching the buoyancy body telescopic movable body connecting plate 14, is hollow and airtight, and is easily expandable and contracted only in the direction of the opposing surface, and one end of this rectangular parallelepiped is attached to a telescopic movable body (central axis side) 12, On both sides of the aforementioned buoyancy body 11, on the other side of the aforementioned buoyancy body telescopic movable body connecting plate 14 that is not on the buoyancy body 11 side, at a position on the lower or upper half of the surface that does not overlap with the aforementioned telescopic movable body (central axis side) 12, there is a rectangular parallelepiped to which one end is attached, the area of ​​which is half the area of ​​the surface of the buoyancy body 11 sandwiching the buoyancy body telescopic movable body connecting plate 14, the interior is hollow and airtight, and it is easy to extend and contract only in the direction of the aforementioned pair of surfaces, and there is a telescopic movable body (outer frame side) 13 to which one end is attached, A gas inlet / outlet hole 15 is provided at the position where the aforementioned buoyancy body 11, the aforementioned buoyancy body telescopic movable body connecting plate 14, and the aforementioned telescopic movable body (central axis side) 12 are connected, A gas inlet / outlet hole 15 is provided at the position where the aforementioned buoyancy body 11, the aforementioned buoyancy body telescopic movable body connecting plate 14, and the aforementioned telescopic movable body (outer frame side) 13 are connected, Equipped with, The central shaft 24, which is the center of the rotating part, is hollow inside and has airtightness that prevents liquid from entering from the outside to the inside, Guide frames 22, each having the same length and diameter, are arranged radially in four directions around the aforementioned central axis 24, with one end attached to each frame. Each guide frame has multiple frames and the same number of frames in each direction. Each of the aforementioned guide frames 22, of which there are multiple and equal numbers in each direction, has an outer frame connecting plate 23 for each extendable and retractable body attached to the other end, The outer frame 21 is attached to each of the aforementioned retractable movable outer frame connection plates 23, Equipped with, The base 33, which serves as the foundation for the support portion during the operation of this device, The support column 32 attached to the aforementioned base 33, The rotating shaft 31 is attached to the aforementioned support column 32, Equipped with, The aforementioned multiple guide frames 22, which are arranged radially in all four directions, are passed through the aforementioned multiple guide frame holes 16 provided in the aforementioned buoyancy body telescopic movable body connecting plates 14. The other end of each of the aforementioned extendable / retractable bodies (on the central axis side) 12 is attached to each of the aforementioned faces of the central axis 24 at the same position as viewed from the center point of the central axis 24. The other end of each of the aforementioned extendable movable bodies (outer frame side) 13 is attached to the aforementioned outer frame connecting plate 23 of each extendable movable body. Gas inlet / outlet holes 25 are provided at the connection points of the aforementioned central shaft 24 and the aforementioned expandable / contractible movable body (central shaft side) 12. The device consists of the aforementioned central shaft 24 attached to the aforementioned rotating shaft 31.

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