CN211908633U - Magnetic driving device - Google Patents

Abstract

The utility model provides a magnetic drive device, includes the base, installation bearing on the base center, installation main shaft on the bearing, fixed driving gear on the main shaft and along circumference equidistance fixed mounting radials, the outer end installation magnet of radials. The base is fixedly arranged with a drive rod gear and an idler wheel at equal intervals along the circumferential direction around the main shaft, the drive rod gear is respectively provided with a bearing and a pin shaft, the other end of the pin shaft is provided with a drive rod, and one end of the drive rod close to the main shaft is provided with a magnet. The driving gear is engaged with the driving rod gear, and the magnets arranged on the driving rod and the magnets arranged on the radial plate of the main shaft are uniformly arranged in parallel at equal intervals in a staggered manner in the same circumferential plane. Each powerful magnet in the mechanism simultaneously acts attraction force and repulsion force on two adjacent and nearest different magnets. Finally, any magnet on the device is acted with force at the same time to drive the spindle to rotate continuously along one direction, so that the magnetic force of the magnet is converted into the power for rotating the spindle.

Description

Magnetic driving device

Technical Field

The invention relates to a magnetic force driving device which is mainly characterized in that a magnet rotor is driven to rotate by utilizing the magnetic field attraction force and the repulsion force of a magnet at the same time, the magnetic field force of the magnet in the magnetic storage stage is fully utilized to do work, and the magnet rotor can be driven to rotate within a certain time period to obtain power to meet the working and living requirements.

Background

The current capacity sources are machines capable of converting other forms of energy into mechanical energy, such as internal combustion engines, external combustion engines, electric motors and the like, and the functions of the machines are to convert chemical energy generated by liquid or gas combustion into heat energy through combustion, convert the heat energy into mechanical energy through expansion and output power to the outside. The engine is a complex machine composed of a plurality of structures and systems, the structural types of the engine are various, but the basic working principle is the same, so the basic structures of the engine are different. The other is a motor powered by a motor mechanism, and the device can rotate by inputting electric energy. And another energy source is clean energy such as wind energy, solar energy and the like provided by nature. And the nuclear energy is large in investment, complex in design and high in safety level.

Disclosure of Invention

The present invention is directed to a magnetic driving device to solve the above problems, and more particularly to a device capable of outputting power continuously for a certain period of time.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a magnetic drive device, includes the base, installation bearing on the base center, installation main shaft on the bearing, along circumference equidistance fixed mounting radials on the main shaft, the outer end installation magnet of radials. The main shaft, the spoke plate and the magnet are fixed together and can rotate along the circumferential direction of the shaft. The base is fixedly arranged with drive rod gears, idle wheels and drive rod gears at equal intervals along the circumferential direction around the main shaft, and the drive rod gears are meshed with the idle wheels and the drive rod gears. The main shaft is provided with a main shaft gear which is engaged with a driving rod gear, the driving rod gear is respectively provided with a bearing, and the bearing is provided with a pin shaft which can rotate on the driving rod gear. The other end of the pin shaft is provided with a driving rod, and one end of the driving rod, which is close to the main shaft, is provided with a magnet. The magnets arranged on the driving rod and the magnets arranged on the radial plate of the spindle are uniformly arranged in parallel at equal intervals in a staggered manner in the same circumferential plane. The magnets arranged on the driving rods and the magnets arranged on the spindle web plate interact with each other by virtue of magnetic force, and after the spindle is determined to turn, one action surface S pole of each magnet arranged on each driving rod corresponds to an action surface N pole of the magnet arranged on the spindle web plate, so that attraction is formed. The N pole of the other action surface of the magnet arranged on the driving rod corresponds to the N pole of the other action surface of the magnet arranged on the next spindle web plate, and repulsion is formed. The magnets mounted on each drive rod simultaneously exert attractive and repulsive forces on two adjacent and nearest different magnets mounted on the spindle web. Because the magnets arranged on the driving rod and the magnets arranged on the radial plate of the main shaft are arranged in parallel and staggered at equal intervals, the strong magnets arranged on the radial plate of the main shaft simultaneously act on the magnets arranged on the driving rod to ensure that the magnets simultaneously act on attraction and repulsion. The adjacent surface magnetic poles of two adjacent and nearest magnets on the radial plate of the spindle are the same, and the opposite surface magnetic poles of the two magnets are also the same. The adjacent surface magnetic poles of two adjacent and nearest magnets on the drive rod magnet are the same, and the opposite surface magnetic poles of the two magnets are also the same. On the plane of the spindle spoke plate magnet rotation, any magnet and the adjacent nearest magnet are in a mode that one side acts on repulsion and the other side acts on attraction. Finally, all the magnets on the device are simultaneously acted with force to drive the spindle to continuously rotate along one direction, so that the magnetic force of the magnets is converted into the power for rotating the spindle.

Compared with the prior art, the invention has the beneficial effects that:

the magnetic driving device has a simple and compact structure and is easy to process. The strong magnets which are uniformly arranged in the circumferential plane in a parallel, equidistant and staggered mode at intervals simultaneously act, the torque is large, the output is uniform, and the strong magnet groups on different layers can be arranged in different circumferential planes to form different levels of magnetic torque and different large-torque output powers.

Description of the drawings:

fig. 1 is an isometric view of a magnetic drive device of embodiment 1.

Fig. 2 is a partial plan view of the magnetic drive apparatus according to embodiment 1.

Fig. 3 is an isometric view of the magnetic drive device of embodiment 2.

Fig. 4 is a partial plan view of the magnetic drive apparatus according to embodiment 2.

Fig. 1 and 2 illustrate: (1) -base, (2) -spindle, (3) -spindle gear, (4) -web, (5) -spindle magnet, (6) -gear, (7) -idler, (8) -drive bar gear, (9) -bearing pin, (10) -drive bar, (11) -drive bar magnet.

Fig. 3 and 4 illustrate: (1) -base, (2) -spindle, (3) -spindle gear, (4) -web, (5) -spindle magnet, (6) -gear, (7) -idler, (8) -drive bar gear, (9) -bearing pin, (10) -drive bar, (11) -drive bar magnet.

The specific implementation mode is as follows:

embodiment 1:

referring to fig. 1 and 2, the magnetic driving device includes a base (1), a bearing is installed in the center of the base (1), a main shaft (2) is installed on the bearing, a main shaft gear (3) is installed on the main shaft (2), radial plates (4) are fixedly installed on the main shaft (2) at equal intervals along the circumference, and a main shaft magnet (5) is installed at the outer end of the radial plates (4). The spindle (2), the spindle gear (3), the spoke plate (4) and the spindle magnet (5) are fixed into a whole and can rotate along the circumferential direction of the spindle. Install gear (6), idler (7), drive lever gear (8) around fixed equidistance arrangement of main shaft (2) along the circumferencial direction on base (1), main shaft gear (3) meshing gear (6), gear (6) drive idler (7), idler (7) meshing drive lever gear (8). The gear (6) and the driving rod gear (8) are respectively provided with a bearing, the bearing is provided with a support pin (9), and the support pin (9) can rotate on the gear (6) and the driving rod gear (8). The other end of the support pin (9) is provided with a driving rod (10), and the end of the driving rod (10) close to the main shaft (2) is provided with a driving rod magnet (11). The driving rod (10) and the driving rod magnet (11) can form rotary reciprocating motion in a circumferential plane by the same-direction rotation of the gear (6) and the driving rod (8). The driving rod magnets (11) and the main shaft magnets (5) are strong permanent magnet magnets, are uniformly arranged in parallel at equal intervals in a staggered mode in the same circumferential plane and exist in pairs, one main shaft magnet (5) must be matched with one driving rod magnet (11), and the driving rod magnet (11) and the main shaft magnets (5) interact with each other by means of magnetic force. After the spindle steering is determined, one action surface S pole of each driving rod magnet (11) corresponds to the action surface N pole of the previous spindle magnet (5), and the other action surface N pole of each driving rod magnet (11) corresponds to the action surface N pole of the next spindle magnet (5). The driving rod magnet (11) acts on the previous spindle magnet (5) with attraction force, and the driving rod magnet (11) acts on the next spindle magnet (5) with repulsion force. Because the drive rod magnets (11) and the main shaft magnets (5) are arranged in a staggered mode at equal intervals, the main shaft magnets (5) act on repulsion force of the previous drive rod magnet (11), the main shaft magnets (5) act on attraction force of the next drive rod magnet (11), and the drive rod magnets (11) form uniform acting force on the main shaft (2) fixed with the main shaft magnets (5) under the combined action of all the magnets, rotate in the same circumferential direction and output power. The main shaft gear (3) rotates along with the main shaft (2) in the same direction, and the meshing gear (6) and the driving rod gear (8) rotate around the center of the shaft. The rotation of the gear (6) and the gear (8) enables the support pin (9), the driving rod (10) and the driving rod magnet (11) to do reciprocating rotary motion. The driving rod magnet (11) fixed on the driving rod (10) enters at a neutral position of the main shaft magnet (5) and leaves at the neutral position after acting, so that the driving rod magnet (11) and the main shaft magnet (5) keep a specific distance for no interference and touch forever, and the main shaft (2) continuously rotates along one direction by means of magnetic force acting. The magnetic driving device can be connected in series and in parallel and is arranged to form a multi-stage magnetic driving mechanism to output large-torque power.

Embodiment 2:

referring to fig. 3 and 4, the magnetic driving device includes a base (1), a bearing is installed in the center of the base (1), a main shaft (2) is installed on the bearing, a main shaft gear (3) is installed on the main shaft (2), radial plates (4) are fixedly installed on the main shaft (2) at equal intervals along the circumference, and a main shaft magnet (5) is installed at the outer ends of the radial plates (4). The spindle (2), the spindle gear (3), the spoke plate (4) and the spindle magnet (5) are fixed into a whole and can rotate along the circumferential direction of the spindle. The base (1) is fixedly provided with support pins (9), a gear (6) and an idler wheel (7) which are arranged at equal intervals along the circumferential direction around the main shaft (2). The bearing is arranged on the support pin (9), the driving rod gear (8) is arranged on the bearing, and the driving rod (10) is fixedly arranged on the driving rod gear (8). The outer end of the driving rod (10) is provided with a driving rod magnet (11). The main shaft gear (3) is meshed with the gear (6), the gear (6) drives the idle gear (7), and the idle gear (7) is meshed with the driving rod gear (8). The synchronism of the main shaft gear (3) and the meshing gear (6) driving the idle gear (7) and the meshing driving rod gear (8) enables the driving rod magnets (11) and the main shaft magnets (5) to be in one-to-one correspondence respectively on the same rotating plane. The main shaft magnets (5) rotate through equal angles (360 degrees/the number of the magnets (5)) at equal angular speed along the circumference, the driving rod magnets (11) are also inserted into the neutral positions of the main shaft magnets (5) at equal angles, so that one action surface S pole of each driving rod magnet (11) corresponds to an action surface N pole of the previous main shaft magnet (5), and the other action surface N pole of each driving rod magnet (11) corresponds to an action surface N pole of the next main shaft magnet (5). The driving rod magnet (11) acts on the previous spindle magnet (5) with attraction force, and the driving rod magnet (11) acts on the next spindle magnet (5) with repulsion force. In the rotating plane of the main shaft magnet (5), because the drive rod magnets (11) and the main shaft magnets (5) are arranged in a staggered mode at equal intervals, one drive rod magnet (11) is inserted into the gap between every two adjacent nearest main shaft magnets (5), so that the main shaft magnet (5) acts on the repulsion force of the previous drive rod magnet (11), the main shaft magnet (5) acts on the attraction force of the next drive rod magnet (11), and the main shaft (2) rotates along one direction under the combined action of all the magnets. The driving rod magnet (11) synchronously enters each other at a constant speed at the main shaft magnet (5) and leaves at the neutral position after acting, so that the driving rod magnet (11) and the main shaft magnet (5) always keep specific distances and do not interfere with each other for touching, and the main shaft (2) continuously rotates along one direction by depending on magnetic force acting and outputs power.

Claims (7)

1. The utility model provides a magnetic drive device, characterized by device structure includes base (1), base (1) installs the bearing in the center, install main shaft (2) on the bearing, install main shaft gear (3) on main shaft (2), along circumference equidistance fixed mounting radials (4) on main shaft (2), main shaft magnet (5) are installed to the outer end of radials (4), main shaft (2), main shaft gear (3), radials (4) and main shaft magnet (5) fixed an organic whole can rotate along the circumferencial direction of axle, arrange installation gear (6) around main shaft (2) along the circumferencial direction fixed equidistance on base (1), idler (7), actuating lever gear (8), main shaft gear (3) meshing gear (6), gear (6) drive idler (7), idler (7) meshing actuating lever gear (8), install the bearing on gear (6) and actuating lever gear (8) respectively, a bearing is provided with a support pin (9), the support pin (9) can rotate on a gear (6) and a driving rod gear (8), the other end of the support pin (9) is provided with a driving rod (10), the driving rod (10) is provided with a driving rod magnet (11) near the end of a main shaft (2), the driving rod (10) and the driving rod magnet (11) can form rotary reciprocating motion in a circumferential plane by the same-direction rotation of the gear (6) and the driving rod gear (8), the driving rod magnet (11) and the main shaft magnet (5) are uniformly arranged in parallel at equal intervals and in an equidistant staggered way in the same circumferential plane, the driving rod magnet (11) and the main shaft magnet (5) are interacted by virtue of magnetic force, after the main shaft is determined to be turned, one action surface S pole of each driving rod magnet (11) corresponds to an action surface N pole of the previous main shaft magnet (5), the other action surface N pole of the driving rod magnet (11) corresponds to an action surface N pole of the next main, make actuating lever magnet (11) to last main shaft magnet (5) effect suction, make actuating lever magnet (11) to next main shaft magnet (5) effect repulsion, because of actuating lever magnet (11) and main shaft magnet (5) equidistance interval staggered arrangement, make main shaft magnet (5) to last actuating lever magnet (11) effect repulsion equally, make main shaft magnet (5) to next actuating lever magnet (11) effect suction, make main shaft (2) rotate along a direction under the combined action of all magnets, main shaft gear (3) rotate along with main shaft (2) syntropy, meshing gear (6) and actuating lever gear (8) rotate around its self axle, gear (6) and actuating lever gear (8) rotate and make back pin (9) and actuating lever (10), actuating lever magnet (11) do reciprocating rotary motion.

2. The magnetic driving device according to claim 1, wherein the main shaft magnets (5) are arranged in a plane of rotation, and the main shaft magnets (5) and the driving rod magnets (11) are arranged in a parallel, equidistant and staggered manner at uniform intervals, and do not interfere with each other during movement and interact with each other by means of magnetic force.

3. The magnetic driving device according to claim 1, wherein an S pole of an active surface of each driving rod magnet (11) corresponds to an N pole of an active surface of the spindle magnet (5) at a previous position to form an attraction force, and an N pole of another active surface of the driving rod magnet (11) corresponds to an N pole of an active surface of the spindle magnet (5) at a next position to form a repulsion force, so that the driving rod magnets (11) arranged at equal intervals in a staggered manner are in non-contact with each other in a circumferential plane and enter gaps of the spindle magnet (5), and the spindle (2) fixed with the spindle magnet (5) can rotate in one direction and output power under the combined action of all the driving rod magnets (11) and the spindle magnet (5).

4. The magnetic driving device according to claim 1, wherein the driving rod magnet (11) fixed on the driving rod (10) enters at the neutral position of the main shaft magnet (5) and leaves at the neutral position after doing work, so that the driving rod magnet (11) and the main shaft magnet (5) which interact with each other by means of magnetic force in the same base plane always keep a specific distance without interfering with each other.

5. Magnetic drive according to claim 1, characterized in that the spindle magnet (5) and the drive rod magnet (11) are present in pairs, and that one spindle magnet (5) must cooperate with one drive rod magnet (11).

6. The magnetic driving device according to claim 1, wherein the magnetic driving device outputs large torque power by forming a multi-stage magnetic driving mechanism in series or in parallel.

7. A magnetic drive apparatus as claimed in claim 1, wherein the apparatus uses a high-force permanent-magnet.

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