CN118911906A - Floating energy rotating device and method using floating energy as power - Google Patents

Abstract

The present invention is to provide a buoyancy rotating device and method using buoyancy as power. The method is to use constant buoyancy to drive the variable cavity of breathable gas based on the conservation of buoyancy energy, so that it can eliminate useless buoyancy and regenerate new required buoyancy to drive the machine to operate. The corresponding device is: a constant box cavity (referred to as a constant buoyancy box) connected in series by a gas hose and fixed up and down as a whole and a retractable box cavity (referred to as a variable buoyancy box) that can change the cavity volume by breathing air are bound in the same direction and equidistantly on a chain belt running around two upper and lower rotating wheels. When the two constant and variable box cavities on both sides of the rotating wheel are reversed, the buoyancy of the constant buoyancy box is used to compress and stretch the variable buoyancy boxes on both sides, so that they can selectively eliminate useless buoyancy and generate required new buoyancy, so as to obtain the power of rising on one side and sinking on the other side to drive the machine to operate.

Description

A buoyancy energy rotation device and method using buoyancy energy as power

Technical field:

The invention discloses a rotating device, which relates to a natural energy rotating device, and in particular to a buoyancy rotating device which uses the buoyancy of water as power.

Background technology:

In order to seek an inexhaustible natural energy to make up for the shortage of existing energy, someone designed a "buoyancy perpetual motion machine" with application number 201110118731.2 as shown in (Figure 1): it is equipped with a number of bullet-shaped pointed cylinders 5 on the chain 7 surrounding the upper and lower sprockets 2. There is a pointed heavy piston 6 in the cylinder that matches the top of the cylinder, and a sealing ring 16 is provided on the heavy piston. The bottom of the cylinder is provided with a water inlet and outlet hole 19, and its top part has a suction and exhaust elbow 10 that communicates with the system air supply pipe 8, and the system air supply pipe is fixed on the chain 7. In addition, outside the upper and lower sprockets, a downward pressure track 4 and an upward support track 12 are provided to cooperate with the small pulley 9 at the top of the cylinder 5 to force the cylinder to run clockwise. When the device is put into water, the heavy piston 6 in the right cylinder slides down to discharge the gas in the cylinder, and the cylinder is filled with water from the water inlet and outlet holes 19 and sinks, while the left cylinder is filled with gas squeezed from the right and becomes a cavity, generating buoyancy and rising. Finally, all cylinders on both sides of the sprocket rise on the left and fall on the right, driving the sprocket 2 to rotate and achieving the invention goal.

A careful analysis will reveal that, first, the friction force generated by the sealing ring 16 of the heavy piston 6 in the cylinder cannot be underestimated. How much drooping potential energy does the heavy piston have to make it slide back and forth? Second, how much resistance does the downward pressure track 4 and the upward support track 12 cause to the cylinder when the cylinder is forced to run clockwise? Third, the potential energy of the heavy piston is used to press the gas on one side to generate buoyancy, and the corresponding buoyancy is also consumed to overcome the resistance caused by these gravity. Therefore, even if the cylinder on the left can generate a little buoyancy, it is a drop in the bucket and will not help.

Summary of the invention:

The present invention is to provide a buoyancy rotating device and method using buoyancy as power. The method is to use constant buoyancy to drive the variable cavity of breathable gas based on the conservation of buoyancy energy, so that it can eliminate useless buoyancy and regenerate new required buoyancy to drive the machine to operate. The corresponding device is: a constant box cavity (referred to as a constant buoyancy box) connected in series by a gas hose and fixed up and down as a whole and a retractable box cavity (referred to as a variable buoyancy box) that can change the cavity volume by breathing air are bound in the same direction and equidistantly on a chain belt running around two upper and lower rotating wheels. When the two boxes on both sides of the rotating wheel are inverted, the buoyancy of the constant buoyancy box is used to compress and stretch the variable buoyancy boxes on both sides, so that it can selectively eliminate useless buoyancy and generate required new buoyancy, so as to obtain the power of rising on one side and sinking on the other side to drive the machine to operate.

Its advantages are:

1. Simple structure, easy to manufacture and low cost.

2. Almost all negative factors (friction, mass potential energy, etc.) are eliminated.

3. No fuel or electricity is needed, it can rotate just by placing it in water.

4. Absolutely environmentally friendly and without any pollution.

5. Safe and risk-free.

6. Energy is water, and it is still water, which is inexhaustible.

7. Although the energy is water, it only relies on the buoyancy of water and does not consume any water at all.

Description of the drawings:

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments:

Figure 1 is a background technology demonstration diagram

Figure 2 is a schematic diagram of the starter box frame

Figure 3 is a top view of the combined structure of the V-shaped buoyancy box

Figure 4 is a main perspective view of the combined structure of the V-shaped buoyancy box

Figure 5 is a main perspective view of the dynamic combination of the V-shaped box panels of the variable float box

Figure 6 is a schematic diagram of the membrane sealing of the variable float box

Figure 7 is a schematic diagram of the finished product of the variable float box

Figure 8 is a front view of the buoyancy conversion starter (variable buoyancy box, constant buoyancy box, box frame combination structure)

Figure 9 is a perspective view of a buoyancy conversion starter (variable buoyancy box, constant buoyancy box, box frame combination structure)

Figure 10 is a diagram of the inverted contraction of the buoyancy conversion starter

Figure 11 is a front view of the combined structure of the buoyancy conversion starter, gas pipe, chain belt and sprocket

Figure 12 is a left view of the combined structure of the buoyancy conversion starter, gas pipe, and chain belt (based on Figure 11)

Figure 13 is a right view of the combined structure of the buoyancy conversion starter, gas pipe, and chain belt (based on Figure 11)

Figure 14 is a top view of the combined structure of the buoyancy conversion starter, gas pipe, and chain belt (based on Figure 11)

Figure 15 is a schematic diagram of the overall assembly of the device

Figure 16 is a schematic diagram of the device operating in water

Specific implementation method:

The overall structure of the present invention is shown in FIG15. It is composed of a bracket 14, a rotating shaft 13, a rotating wheel 12, an endless chain belt 11 that can run around two rotating wheels 12, a gas delivery hose 10, and a buoyancy conversion starter (referred to as starter Q) FIG8. The starter Q is composed of a box frame K (FIG2) and a combination of two variable box cavities (referred to as variable buoyancy box B) FIG6 and a sealed box cavity (referred to as constant buoyancy box H) that can change its volume through the expansion and contraction of breathing air in the box frame K.

The box frame K is composed of two square vertical frames 1 with square supporting frames 2 welded to the bottom edges. The supporting frame 2 is smaller than the vertical frame 1, and the minimum angle between the two planes is about 60 degrees. The two congruent vertical frames are connected by a connecting handle 3 in the middle to form a symmetrical whole (Figure 2).

The variable float box B is formed by two rectangular box boards 4 with breathing holes 5 connected by hinges 6 into a V-shaped body (Figure 3-Figure 5), and then sealed with a non-breathable soft film 7 (Figure 6, Figure 7), and finally the joint of the two box boards is sealed with a non-breathable flexible film material 8 (Figure 7).

The box plate 4 at one end of the variable float box B is fixed (fixed) on the supporting frame 2 in the box frame K, and an independently sealed constant float box H is installed outside the box plate 4 at the other unfixed end of the variable float box B. The variable float box B, the constant float box H and the box frame K together constitute the starter Q (Figure 8-Figure 10). Both sides of the constant float box H and the variable float box B must not touch the vertical frame 1 of the box frame K. All starters Q are movably mounted on the chain belt 11 at the same direction and at equal distances by the buckle 9 at the box frame connecting handle 3 (Figure 11-14); all variable float boxes B are connected in series with each other by the air supply hose 10 through the breathing hole 5 (Figure 11-Figure 13), forming an internal air circulation system - that is, a "buoyancy rotation device powered by buoyancy" (Figure 15).

When the device is placed in water (Figure 16), the fixed ends of the box plate 4 of the right variable float box B and the supporting frame 2 of the box frame K are at the top and the constant float box H is at the bottom. The originally inflated variable float box B is pushed and squeezed by the buoyancy F of the constant float box H below, and the air 15 in the box is discharged to the air pipe 10 and the left variable float box B and loses its own buoyancy; at the same time, the box plate 4 of the left variable float box B and the supporting frame 2 of the box frame K are at the bottom and the constant float box H is at the top. The originally deflated variable float box B is stretched by the floating constant float box H above to form a vacuum, and at the same time, the air 15 discharged from the compressed variable float box B on the right is sucked in through the air pipe 10 to swell and generate buoyancy 16.

At this time, excluding the self-weight factor of the starters Q on both sides of the runner, in terms of the buoyancy of a single starter Q, the starter Q on the right side only has the buoyancy F of the constant buoyancy box H, while the starter Q on the left side has the added buoyancy 16 of the variable buoyancy box B in addition to the buoyancy F of the constant buoyancy box H. That is, the starter Q on the left side has one more buoyancy 16 than the starter Q on the right side. Obviously, the buoyancy F+16 of the variable buoyancy box B on the left side of the runner 12 is greater than the buoyancy F of the variable buoyancy box B on the right side, that is, The sum of several newly generated buoyancy 16 is equal to the total buoyancy 17. When the total buoyancy 17 is greater than all the resistances generated by the friction of the machine, the chain belt 11 on the left is pulled up and then the rotating wheel 12 is driven to rotate clockwise, finally achieving the design goal of the present invention.

In addition, although the water pressure is different at different depths, in water at the same depth, the water pressure on the variable float boxes B on both sides of the machine is equal, so the water pressure will not have a negative impact on the realization of this design goal.

Claims (8)

1. A buoyancy energy rotation device and method using buoyancy energy as a driving force, wherein the device is composed of a bracket 14, a rotating shaft 13, a sprocket wheel 12, a conveying chain belt 11, an air delivery hose 10 and a starter Q, wherein the starter Q includes a box frame K, a variable buoyancy box B and a constant buoyancy box H; the characteristic is that a method for obtaining and eliminating new required regenerative buoyancy energy is performed by using a constant buoyancy device, namely, a constant buoyancy box H; the method is to install a plurality of buoyancy energy conversion starters Q in a forward direction and at equal intervals on a chain belt 11 that can be operated around two upper and lower rotating wheels 12, and to use the buoyancy of the constant buoyancy box H in the starter Q under water to convert a retractable air cavity, namely, a variable buoyancy box, into a retractable air cavity. The buoyancy box B is compressed to expel the gas 15 inside the box, thereby eliminating buoyancy and sinking, and at the same time, the exhausted gas is filled into the retractable air cavity on the other side, the variable buoyancy box B, which is opposite to it, through the air pipe 10; similarly, the buoyancy of the constant buoyancy box H is used to stretch the latter retractable air cavity, the variable buoyancy box B, to form a negative pressure, and at the same time, the exhausted gas 15 of the former variable buoyancy box B is sucked in through the air hose 10 to expand its cavity and generate buoyancy and rise; that is, the buoyancy of a constant buoyancy device, the constant buoyancy box H under water, is used to simultaneously generate the required new buoyancy for the present invention and eliminate the original useless buoyancy to do work, thereby obtaining additional buoyancy energy to drive the machine to rotate. 2. According to claim 1, a buoyancy rotation device and method using buoyancy as power, the device is composed of a bracket 14, a rotating shaft 13, a sprocket 12, a conveyor chain 11, an air hose 10 and a buoyancy conversion starter Q, and the buoyancy conversion starter Q includes a box frame K, a variable buoyancy box B and a constant buoyancy box H; it is characterized in that the core components of the buoyancy conversion starter Q are composed of the variable buoyancy box B and the constant buoyancy box H. 3. A buoyancy rotation device and method using buoyancy as power according to claims 1 and 2, characterized in that the variable buoyancy box B is a cavity that can change its own volume (i.e. buoyancy) by sucking and exhausting gas. 4. A buoyancy rotating device using buoyancy as power according to claims 1 and 2, characterized in that the constant buoyancy tank H is an independently sealed cavity. 5. A buoyancy rotating device using buoyancy as power according to claims 1 and 2, characterized in that: only one end of the variable buoyancy box B is fixedly connected to the supporting frame 2 of the box frame K. 6. A buoyancy rotating device using buoyancy as power according to claims 1 and 2, characterized in that the constant buoyancy tank H is connected to the variable buoyancy tank B in an invariable manner. 7. A buoyancy rotating device using buoyancy as power according to claims 1 and 2, characterized in that: the variable buoyancy boxes B are connected to each other by air pipes 10. 8. A buoyancy energy rotating device using buoyancy energy as power according to claims 1 and 2, characterized in that: the buoyancy energy conversion starter Q is installed in a forward direction on the chain belt 11 that can run around the rotating wheel 12.