阅读说明：本技术 一种真空发电装置 (Vacuum power generation device ) 是由 黄文庆 于 2020-07-24 设计创作，主要内容包括：本发明属于发电技术领域,公开了一种真空发电装置,包括：真空壳体；第一磁铁,设置在所述真空壳体外；用于驱动所述第一磁铁朝向或远离所述真空壳体位移的驱动机构；第二磁铁,所述第二磁铁与所述第一磁铁磁性相斥；旋转螺杆,设置在所述真空壳体内,且设置在所述第二磁铁上；第一传动轮,设置在所述旋转螺杆上；第二传动轮,安装在所述真空壳体内的发电机的转轴上；以及发电机,其转子设置在所述转轴上；当所述驱动机构驱动所述第一磁铁朝向所述真空壳体位移时,所述第二磁铁朝向所述第二传动轮位移并使所述第一传动轮与所述第二传动轮传动连接。发电机在工作状态下无任何空气阻力,在相同结构、相同功率的前提下,可提高发电效率。(The invention belongs to the technical field of power generation, and discloses a vacuum power generation device, which comprises: a vacuum housing; a first magnet disposed outside the vacuum housing; a drive mechanism for driving the first magnet to displace towards or away from the vacuum housing; a second magnet that magnetically repels the first magnet; the rotating screw is arranged in the vacuum shell and arranged on the second magnet; the first transmission wheel is arranged on the rotary screw rod; the second driving wheel is arranged on a rotating shaft of the generator in the vacuum shell; and a generator, the rotor of which is arranged on the rotating shaft; when the driving mechanism drives the first magnet to move towards the vacuum shell, the second magnet moves towards the second driving wheel and enables the first driving wheel to be in transmission connection with the second driving wheel. The generator has no air resistance in the working state, and can improve the generating efficiency on the premise of the same structure and the same power.)

1. A vacuum power generation device, comprising:

a vacuum housing;

a first magnet disposed outside the vacuum housing;

the driving mechanism is used for driving the first magnet to move towards or away from the vacuum shell and is arranged outside the vacuum shell, and the output end of the driving mechanism is connected with the first magnet;

a second magnet that magnetically repels the first magnet;

the rotating screw is arranged in the vacuum shell and arranged on the second magnet;

the first driving wheel is arranged on the rotating screw rod, and an internal threaded hole of the first driving wheel is matched with the rotating screw rod;

the second driving wheel is arranged on a rotating shaft of the generator in the vacuum shell;

and a generator, the rotor of which is arranged on the rotating shaft;

when the driving mechanism drives the first magnet to move towards the vacuum shell, the second magnet moves towards the second driving wheel and enables the first driving wheel to be in transmission connection with the second driving wheel;

when the driving mechanism drives the first magnet to move away from the vacuum shell, the second magnet and the first driving wheel are both away from the second driving wheel to move.

2. The vacuum power generation apparatus according to claim 1, wherein: the driving mechanism is a manual driving mechanism, and the manual driving mechanism comprises a hand pushing part used for enabling the first magnet to move towards or away from the vacuum shell.

3. The vacuum power generation apparatus according to claim 2, wherein: the hand push part is arranged on the outer side of the vacuum shell in a sliding mode.

4. The vacuum power generation apparatus according to claim 3, wherein: the hand-push part is arranged on the outer side of the vacuum shell in a sliding mode through a first sliding block assembly;

the first sliding block assembly comprises a first sliding block and a first sliding rod, the first sliding block is connected with the hand pushing portion, the first sliding block is arranged on the first sliding rod in a sliding mode, and the first sliding rod is located on the outer side of the vacuum shell.

5. The vacuum power generation apparatus according to claim 4, wherein: the number of the first sliding block assemblies is two, and the two groups of the first sliding block assemblies are positioned on two sides of the hand pushing portion.

6. The vacuum power generation apparatus according to claim 5, wherein: and a sealing block for preventing the first sliding block from sliding away from the first sliding rod is arranged at the rear side of the first sliding rod.

7. The vacuum power generation apparatus according to claim 6, wherein: the second magnet is arranged in the vacuum shell in a sliding mode through a second sliding block assembly;

the sliding direction of the second sliding block component is consistent with that of the first sliding block component.

8. The vacuum power generation apparatus according to claim 1, wherein: the first driving wheel is provided with first meshing teeth, and the second driving wheel is provided with second meshing teeth meshed with the first meshing teeth.

9. The vacuum power generation apparatus according to claim 8, wherein: when the second meshing teeth are meshed with the first meshing teeth, the second meshing teeth are positioned on the front sides of the first meshing teeth.

10. The vacuum power generation apparatus according to claim 1, wherein: the second driving wheel is arranged on the rotating shaft through an annular mounting part;

the rotating shaft is installed in the vacuum shell through a rotating bearing.

Technical Field

The invention belongs to the technical field of power generation, and particularly relates to a vacuum power generation device.

Background

People want to improve the power generation efficiency of the generator by all methods, reduce the power generation cost, prolong the service life of the generator, expand the types of the generator to adapt to the power requirements of different environments, improve the power generation amount of the generator and reduce the energy consumption of the generator, which is a necessary way for the development of the generator. With the development of science and technology, the research on various power generation motors becomes mature day by day, but the purposes of improving the power generation capacity of the generator and reducing the energy consumption of the generator are the endless targets of the generator industry.

At present, all the generators in the world work in the air, and the rotating speed of a rotor of a motor is directly influenced by air resistance, so that the generating efficiency of the generator is reduced. To this end, we propose a vacuum power generation device.

Disclosure of Invention

In order to solve the above problems in the prior art, the present invention aims to provide a vacuum power generation device.

The technical scheme adopted by the invention is as follows:

a vacuum power generation device comprising:

a vacuum housing;

a first magnet disposed outside the vacuum housing;

the driving mechanism is used for driving the first magnet to move towards or away from the vacuum shell and is arranged outside the vacuum shell, and the output end of the driving mechanism is connected with the first magnet;

a second magnet that magnetically repels the first magnet;

the rotating screw is arranged in the vacuum shell and arranged on the second magnet;

the first driving wheel is arranged on the rotating screw rod, and an internal threaded hole of the first driving wheel is matched with the rotating screw rod;

the second driving wheel is arranged on a rotating shaft of the generator in the vacuum shell;

and a generator, the rotor of which is arranged on the rotating shaft;

when the driving mechanism drives the first magnet to move towards the vacuum shell, the second magnet moves towards the second driving wheel and enables the first driving wheel to be in transmission connection with the second driving wheel;

when the driving mechanism drives the first magnet to move away from the vacuum shell, the second magnet and the first driving wheel are both away from the second driving wheel to move.

Further, the driving mechanism is a manual driving mechanism including a hand-pushing portion for displacing the first magnet toward or away from the vacuum housing.

Further, the hand pushing part is arranged on the outer side of the vacuum shell in a sliding mode.

Further, the hand-push part is arranged on the outer side of the vacuum shell in a sliding mode through a first sliding block assembly;

the first sliding block assembly comprises a first sliding block and a first sliding rod, the first sliding block is connected with the hand pushing portion, the first sliding block is arranged on the first sliding rod in a sliding mode, and the first sliding rod is located on the outer side of the vacuum shell.

Furthermore, the number of the first sliding block assemblies is two, and the two first sliding block assemblies are located on two sides of the hand pushing portion.

Further, a sealing block for preventing the first sliding block from sliding away from the first sliding rod is arranged on the rear side of the first sliding rod.

Further, the second magnet is slidably arranged in the vacuum shell through a second sliding block assembly;

the sliding direction of the second sliding block component is consistent with that of the first sliding block component.

Furthermore, a first meshing tooth is arranged on the first driving wheel, and a second meshing tooth meshed with the first meshing tooth is arranged on the second driving wheel.

Further, when the second engaging tooth is engaged with the first engaging tooth, the second engaging tooth is located on the front side of the first engaging tooth.

Further, the second driving wheel is arranged on the rotating shaft through an annular mounting part;

the rotating shaft is installed in the vacuum shell through a rotating bearing.

The invention has the beneficial effects that:

the generator has no air resistance in the working state, the rotating speed of the rotor can be increased by 2-3 times because of no air resistance influence in a vacuum environment, and the generating efficiency can be improved on the premise of the same structure and the same power.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic structural diagram of the first driving wheel and the second driving wheel in driving connection according to the invention.

FIG. 3 is a schematic structural view of embodiment 3.

Fig. 4 is a schematic structural view of the second engaging tooth engaged with the first engaging tooth.

Fig. 5 is a schematic structural view of the pneumatic drive mechanism.

Fig. 6 is a schematic structural view of the drive mechanism of embodiment 6 (when the pressing lever 91 is horizontally disposed).

Fig. 7 is a schematic structural view of the drive mechanism of embodiment 6 (when the pressing lever 91 is disposed in the longitudinal direction).

In the figure: 10-a vacuum shell; 21-a first magnet; 22-a second magnet; 30-rotating the screw; 41-a first drive wheel; 411-first engaging teeth; 42-a second transmission wheel; 421-second engaging teeth; 43-an annular mounting portion; 51-a rotating shaft; 52-a rotor; 53-a stator; 60-a hand-pushing part; 71-a first slider; 72-a first slide bar; 73-a sealing block; 80-a cylinder; 81-a piston rod; 82-connecting blocks; 91-a pressure bar; 911-rotating shaft; 92-a pressure ring; 93-connecting rod; 94-a scaffold; 95-a drive shaft; 96-pulley; 97-second return spring.

Detailed Description

The invention is further explained below with reference to the drawings and the specific embodiments.