阅读说明：本技术 反重力动力装置 (Antigravity power device ) 是由 钱力群 于 2020-05-25 设计创作，主要内容包括：本申请公开了反重力动力装置,包括架体,以及可活动地设于所述架体上的传动轴,所述传动轴上设有套设有旋转飞轮；所述反重力动力装置还包括套设于所述旋转飞轮上的真空浮力单元,所述真空浮力单元包括：套设于所述旋转飞轮外的壳体,所述壳体内设有真空腔,所述真空腔内设有旋转壳体,所述旋转壳体内设有供所述旋转飞轮旋转的真空旋转腔。本申请通过传动轴连接外部旋转机构启动旋转,所述真空浮力单元内抽真空,所述真空浮力单元内的真空旋转腔和真空腔呈真空状态并达到预估值时,空气阻力减小,摩擦力减小,根据能量守恒定律,所述旋转飞轮所受引力和重力势能转换为动能,使得所述旋转飞轮的动力势能提高,提高转动的速率。(The application discloses an antigravity power device, which comprises a frame body and a transmission shaft movably arranged on the frame body, wherein a rotary flywheel is sleeved on the transmission shaft; the antigravity power device is still located including the cover vacuum buoyancy unit on the rotatory flywheel, vacuum buoyancy unit includes: the casing is sleeved outside the rotating flywheel, a vacuum cavity is arranged in the casing, a rotating casing is arranged in the vacuum cavity, and a vacuum rotating cavity for rotating the rotating flywheel is arranged in the rotating casing. This application is connected outside rotary mechanism through the transmission shaft and is started rotatoryly, evacuation in the vacuum buoyancy unit, rotatory chamber of vacuum in the vacuum buoyancy unit and vacuum cavity are the vacuum state and when reaching the estimate value, and air resistance reduces, and frictional force reduces, according to the law of conservation of energy, rotatory flywheel receives gravitation and gravitational potential energy conversion kinetic energy into, makes the power potential energy of rotatory flywheel improves, improves pivoted speed.)

1. The antigravity power device is characterized by comprising a frame body (10) and a transmission shaft (100) movably arranged on the frame body (10), wherein a rotating flywheel (130) is sleeved on the transmission shaft (100);

the antigravity power device further comprises a vacuum buoyancy unit (20) sleeved on the rotating flywheel (130), wherein the vacuum buoyancy unit (20) comprises: the rotary flywheel comprises a shell (210) sleeved outside the rotary flywheel (130), wherein a vacuum cavity (211) is arranged in the shell (210), a rotary shell (220) is arranged in the vacuum cavity (211), and a vacuum rotary cavity (221) for the rotary flywheel (130) to rotate is arranged in the rotary shell (220).

2. The antigravity power plant according to claim 1, characterized in that: the rotating shell (220) is arranged on one side of the rotating flywheel (130), and when the rotating flywheel (130) moves, the rotating shell repeatedly enters and exits the vacuum rotating cavity (221) of the rotating shell (220).

3. The antigravity power plant according to claim 1, characterized in that: a plurality of oil accommodating grooves (2211) are formed in the vacuum rotating cavity (221).

4. The antigravity power plant according to claim 1, characterized in that: an oil containing cavity (131) for containing hydraulic oil is arranged on the rotating flywheel (130).

5. The antigravity power plant according to claim 4, characterized in that: when the rotating flywheel (130) rotates into the vacuum rotating cavity (221), the distance between the rotating flywheel (130) and the cavity wall (2212) of the vacuum rotating cavity (221) is 1 mm;

the depth h1 of hydraulic oil contained in the oil containing cavity (131) is one eighth of the thickness h2 of the rotating flywheel (130), and a plurality of baffles (132) which are staggered relative to the oil containing cavity (131) are arranged in the oil containing cavity (131).

6. The antigravity power plant according to claim 1, characterized in that: the rotating flywheel (130) comprises a straight surface and arc surfaces connected with two ends of the straight surface;

the rotating shell (220) is arranged in a semicircle shape.

7. The antigravity power plant according to claim 1, characterized in that: the drive shaft (100) includes: the flywheel type transmission device comprises a first transmission shaft (110) and a second transmission shaft (120), wherein the first transmission shaft (110) is in transmission connection with the second transmission shaft (120), and the rotating flywheel (130) is sleeved on the first transmission shaft (110) and/or the second transmission shaft (120).

8. The antigravity power plant according to claim 7, characterized in that: a first rotating gear (111) and a second rotating gear (121) which are in meshing transmission are respectively arranged on the first transmission shaft (110) and the second transmission shaft (120);

the rotating shell (220) is made of a titanium alloy material.

9. The antigravity power plant according to claim 1, characterized in that: the air pressure in the vacuum chamber (211) and/or the vacuum rotation chamber (221) reaches minus 1.5 atmospheres.

10. The antigravity power plant according to claim 1, characterized in that: the rotary shell (220) and/or the shell (210) are provided with an air outlet and an air inlet, the air outlet is connected with a vacuum pump for vacuumizing, and the air inlet is connected with an air conveying pump for conveying air.

[ technical field ] A method for producing a semiconductor device

The application relates to the field of floating energy power, in particular to a antigravity power device.

[ background of the invention ]

The existing flywheel is driven by a motor, but the speed of transmission is influenced by materials and gravity, and the existing flywheel also has an improved space, but the structure adopted by the existing high-speed transmission is more complex.

[ summary of the invention ]

The current flywheel of this application solution is driven through the motor, but driven speed receives the influence of material and gravity, still has the space that improves, but the comparatively complicated technical problem of structure that present high-speed transmission adopted.

In order to solve the technical problem, the method is realized by the following technical scheme:

an antigravity power device comprises a frame body and a transmission shaft movably arranged on the frame body, wherein a rotating flywheel is sleeved on the transmission shaft;

the antigravity power device is still located including the cover vacuum buoyancy unit on the rotatory flywheel, vacuum buoyancy unit includes: the casing is sleeved outside the rotating flywheel, a vacuum cavity is arranged in the casing, a rotating casing is arranged in the vacuum cavity, and a vacuum rotating cavity for rotating the rotating flywheel is arranged in the rotating casing.

The rotating shell is arranged on one side of the rotating flywheel, and the rotating flywheel repeatedly enters and exits the vacuum rotating cavity of the rotating shell when moving.

And a plurality of oil accommodating grooves are formed in the vacuum rotating cavity.

And an oil containing cavity for containing hydraulic oil is arranged on the rotating flywheel.

When the rotating flywheel rotates into the vacuum rotating cavity, the distance between the rotating flywheel and the cavity wall of the vacuum rotating cavity is 1 mm;

the depth h1 that can hold hydraulic oil in the oil containing cavity is one eighth of the thickness h2 of the rotating flywheel, and a plurality of baffles that are staggered relative to the oil containing cavity are also arranged in the oil containing cavity.

The rotating flywheel comprises a straight surface and arc surfaces connected with two ends of the straight surface;

the rotary shell is arranged in a semicircle shape.

The transmission shaft includes: the first transmission shaft and the second transmission shaft are in transmission connection, and the rotating flywheel is sleeved on the first transmission shaft and/or the second transmission shaft;

a first rotating gear and a second rotating gear which are in meshing transmission are respectively arranged on the first transmission shaft and the second transmission shaft;

the rotating shell is made of a titanium alloy material.

The air pressure in the vacuum cavity and/or the vacuum rotary cavity reaches negative 1.5 atmospheric pressures.

The rotary shell and/or the shell are provided with an air outlet and an air inlet, the air outlet is connected with a vacuum pump for vacuumizing, and the air inlet is connected with an air conveying pump for conveying air.

Compared with the prior art, the invention has the following outstanding advantages:

this application is connected outside rotary mechanism through the transmission shaft and is started rotatoryly, evacuation in the vacuum buoyancy unit, rotatory flywheel receive gravity and vacuum state's influence rotatory down in the vacuum buoyancy unit, when vacuum rotatory chamber and the vacuum cavity evacuation in the vacuum buoyancy unit reach the estimate value, air resistance reduces, and frictional force reduces, according to the law of conservation of energy, rotatory flywheel receives gravitation and gravitational potential energy conversion kinetic energy into, makes the kinetic potential energy of rotatory flywheel improves pivoted speed.

[ description of the drawings ]

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a perspective view of the antigravity power unit of the present application.

FIG. 2 is a perspective view of a first perspective of the vacuum buoyancy unit of the antigravity power plant of the present application.

FIG. 3 is a perspective view from a second perspective of the vacuum buoyancy unit of the antigravity power plant of the present application.

FIG. 4 is a cross-sectional view of the vacuum buoyancy unit of the antigravity power plant of the present application.

FIG. 5 is a cross-sectional view of a rotating flywheel of the antigravity power plant of the present application.

Fig. 6 is a perspective view of a rotating housing of the antigravity power unit of the present application.

[ detailed description ] embodiments

The present application will be described in further detail below with reference to the accompanying drawings by way of specific embodiments.

As shown in fig. 1 to 6, an antigravity power device is characterized by comprising a frame body 10 and a transmission shaft 100 movably arranged on the frame body 10, wherein a rotating flywheel 130 is sleeved on the transmission shaft 100; the antigravity power device further comprises a vacuum buoyancy unit 20 sleeved on the rotating flywheel 130, wherein the vacuum buoyancy unit 20 comprises: the casing 210 is sleeved outside the rotating flywheel 130, a vacuum cavity 211 is disposed in the casing 210, a rotating casing 220 is disposed in the vacuum cavity 211, and a vacuum rotating cavity 221 for rotating the rotating flywheel 130 is disposed in the rotating casing 220. This application is connected outside rotary mechanism through transmission shaft 100 and is started rotatoryly, evacuation in the vacuum buoyancy unit 20, rotatory flywheel 130 receives gravity and vacuum state's influence rotatory down in the vacuum buoyancy unit 20, when the rotatory chamber 221 of vacuum in the vacuum buoyancy unit 20 and vacuum cavity 211 evacuation reach the estimate value, air resistance reduces, and frictional force reduces, according to the law of conservation of energy, gravitation and gravitational potential energy that rotatory flywheel 130 receives convert kinetic energy into, make the kinetic potential energy of rotatory flywheel 130 improves, improves pivoted speed.

An oil containing cavity 131 for containing hydraulic oil is arranged on the rotating flywheel 130. Hydraulic oil can be arranged in the oil accommodating cavity 131, certain buoyancy can be provided for the hydraulic oil in a vacuum state, and meanwhile, the power potential energy of the rotating flywheel 130 is improved through the conversion of the gravitational potential energy and the kinetic energy, so that the rotating speed is increased.

The vacuum buoyancy unit 20 includes: the casing 210 is sleeved outside the rotating flywheel 130, a vacuum cavity 211 is disposed in the casing 210, a rotating casing 220 is disposed in the vacuum cavity 211, and a rotating cavity 221 for rotating the rotating flywheel 130 is disposed in the rotating casing 220. The vacuum rotary cavity 221 and the housing 210 are vacuumized, so that the gravity of the rotary flywheel 130 is reduced, the power potential energy is increased, and the rotation speed is increased.

The rotating housing 220 is disposed at one side of the rotating flywheel 130, and the rotating flywheel 130 repeatedly enters and exits the vacuum rotating cavity 221 of the rotating housing 220 when moving. Rotatory flywheel 130 part is equipped with holds oil chamber 131, rotatory casing 220 spaced passes through the conversion that accelerated motion and uniform motion were realized to rotatory chamber 221 in vacuum, is finally in a stable motion state, and this application connects outside rotary mechanism start-up rotation through first transmission shaft 110 and second transmission shaft 120, and the appearance oil chamber 131 on the rotatory flywheel 130 brings hydraulic oil into rotatory chamber 221 in vacuum when rotatory, because through evacuation in the vacuum chamber 211, rotatory flywheel 130 is rotatory under the influence of gravity and buoyancy, when the vacuum chamber 211 evacuation reaches the estimate value, be the vacuum state in the vacuum chamber 211, air resistance reduces, and frictional force reduces, according to the law of conservation of energy, the gravitation and the gravitational potential energy that rotatory flywheel 130 receives convert kinetic energy into kinetic energy, make the kinetic potential energy of rotatory flywheel 130 improves, improves pivoted speed.

A plurality of oil accommodating grooves 2211 are arranged in the vacuum rotating cavity 221. Because the rotating speed of the rotating flywheel 130 is unstable when the rotating flywheel is just started, the hydraulic oil in the oil accommodating cavity 131 is easy to fly out, and the oil accommodating groove 2211 is used for accommodating the flying hydraulic oil, so that the rotating flywheel 130 is prevented from contacting with the hydraulic oil when rotating, and the rotation of the rotating flywheel 130 is prevented from being influenced.

When the rotating flywheel 130 rotates into the vacuum rotating cavity 221, the distance between the rotating flywheel 130 and the cavity wall 2212 of the vacuum rotating cavity 221 is 1 mm; the depth h1 of the oil containing cavity 131 capable of containing hydraulic oil is one eighth of the thickness h2 of the rotating flywheel 130, and a plurality of baffles 132 which are staggered relative to the oil containing cavity 131 are arranged in the oil containing cavity 131. When the rotating flywheel 130 rotates into the vacuum rotating cavity 221, the distance between the rotating flywheel 130 and the cavity wall 2212 of the vacuum rotating cavity 221 is 1mm, so that the rotating flywheel 220 is prevented from abutting against the vacuum rotating cavity 221, the rotating flywheel 130 and the rotating shell 220 are prevented from being damaged, and the distance between the rotating flywheel 130 and the rotating shell 220 is 1mm, so that the rotating flywheel has good transmission performance; the oil containing cavity 131 is used for containing hydraulic oil, when the vacuum rotating cavity 221 in the rotating shell 220 is in a vacuum state, the gravity of the rotating flywheel 130 is reduced, the hydraulic oil provides buoyancy, the rotating flywheel 130 is reduced, the rotating speed is improved, the rotating force of the rotating flywheel 130 is increased, and the baffle 132 prevents the rotating flywheel 130 from being started and throws away the hydraulic oil in the oil containing cavity 131.

A first rotating gear 111 and a second rotating gear 121 which are in meshing transmission are respectively arranged on the first transmission shaft 110 and the second transmission shaft 120; the rotating housing 220 is made of a titanium alloy material. The rotating shell 220 is made of a titanium alloy material and has high hardness; the first rotating gear 111 and the second rotating gear 121 are used for driving the first transmission shaft 110 and the second transmission shaft 120, so that the number of transmissions is increased, and the transmission efficiency is improved, wherein the first transmission shaft 110 and the second transmission shaft 120 are externally connected with a motor to rotate.

The pressure in the vacuum chamber 211 and/or the vacuum rotation chamber 221 reaches minus 1.5 atmospheres. The vacuum chamber 211 and/or the vacuum rotation chamber 221 have a better vacuum effect when the air pressure reaches minus 1.5 atmospheres.

One side of the rotating flywheel 130 is a straight surface, the peripheral side of the rotating flywheel 130 is an arc surface, and two ends of the arc surface are connected with the straight surface; the rotating housing 220 is disposed in a semicircle. The oil containing cavities 131 on the rotating flywheel 130 enter the rotating shell 220 at intervals to continuously convert potential energy and kinetic energy, so that the working intensity of an external motor is reduced, the rotating speed is improved, the rotating force of the rotating flywheel 130 is increased, the rotating shell 220 is in a semicircular shape, materials are saved, a certain pressure difference can be formed between the vacuum rotating cavity 221 and the vacuum cavity 211, and the conversion of the potential energy and the kinetic energy of the rotating flywheel 130 is adjusted.

The rotary shell 220 and/or the shell 210 are provided with an air outlet and an air inlet, the air outlet is connected with a vacuum pump for vacuumizing, and the air inlet is connected with an air conveying pump for conveying air. The vacuum pump is used for adjusting the vacuum cavity 211 and/or the vacuum rotary cavity 221 to be in a vacuum state or a semi-vacuum state, increasing the transmission rate of the rotary flywheel 130, or inputting air, increasing air resistance, and stopping the rotary flywheel 130, when in use, the rotary housing 220 and the housing 210 start the vacuum pump at the same time, and the vacuum pump is started all the time to enable the air pressure in the vacuum cavity 211 and/or the vacuum rotary cavity 221 to reach negative 1.5 atmospheric pressures, so that the phenomenon that after the vacuum pump is turned off, the atmospheric pressure in the vacuum cavity 211 and/or the vacuum rotary cavity 221 is increased to influence the rotation of the rotary flywheel 130 is avoided.

As described above, the embodiments of the present application have been described in detail, but the present application is not limited to the above embodiments. Even if various changes are made in the present application, the protection scope of the present application is still included.