An electric hybrid rotary power-assisted device

Abstract

This invention discloses an electric hybrid power-driven rotary booster device, comprising a bottom mounting base and a rotating column. The device is connected to multiple air turbines. When these turbines operate, the resulting high-pressure air flows through inclined pipes towards the inclined plane structure. The high-pressure air from multiple directions acts on the surface of the inclined plane structure, causing the multiple annular array of inclined planes to move in the same direction. This same-direction movement then drives the rotating column to rotate. Simultaneously, an electric current is applied. Based on electromagnetic principles and the attraction and repulsion of like poles, the main iron core and permanent magnet generate the same magnetic poles at their opposite ends. Under the influence of electromagnetic effects, the rotational torque is further increased. Driven by wind power, the rotating column rotates with strong rotational inertia. Each time it reaches a specific position, the electromagnetic field further enhances this rotational inertia.

Description

Technical Field

[0001] This invention relates to the field of rotary power assist devices, specifically an electric hybrid rotary power assist device. Background Technology

[0002] Currently, in order to increase the rotational kinetic energy of rotating mechanisms, rotational booster devices are used. Most existing rotational booster devices are turbochargers. Since their boosting source comes from only one turbine, their boosting effect is relatively poor. Summary of the Invention

[0003] The purpose of this invention is to provide an electric hybrid rotary booster device to solve the problems mentioned in the background art.

[0004] To achieve the above objectives, the present invention provides the following technical solution: an electric hybrid power rotary assist device, comprising a bottom mounting base and a rotating column. Two opposing column mounting bases are mounted on the upper surface of the bottom mounting base. A main column shell is fixed between the tops of the two column mounting bases. A main component mounting hole is provided at the center of the interior of the main column shell. An integral annular protrusion structure is provided at the center of the circumferential side of the rotating column. The two edges of the annular protrusion structure are mounted on the inner wall of the center of the main component mounting hole via a main bearing. Multiple annular array-type inclined plate structures are provided on the two annular sides of the annular protrusion structure, each inclined plate structure being an inclined surface structure. The circumferential surface of the main column shell... The side has multiple annular array-shaped main protrusions, each containing a main iron core. Each main iron core has a main coil sleeved on its side, and each main coil has a main power input terminal with a main wire installed. The annular protrusions contain multiple annular arrays of permanent magnets, and both the permanent magnets and the main iron cores have beveled ends with the same slope. The main column shell contains multiple oblique pipes connecting its outer and inner circular sides, and each oblique pipe has a pipe docking port at its end facing the outer circular side. A main rotating column is fixed at the center of one end face of the rotating column, and a main connecting flange is installed at the end of the main rotating column.

[0005] Furthermore, the angle between the plane of the inclined plate structure and the virtual line of the inclined plate structure pointing to the center line of the rotating cylinder is an acute angle.

[0006] Furthermore, the angle between the plane of the permanent magnet and the virtual line pointing to the center line of the rotating cylinder is an acute angle.

[0007] Furthermore, the inclined plate structure and the permanent magnet are tilted in the same direction.

[0008] Furthermore, the centerline of the inclined pipe and the plane of the inclined plate structure can be perpendicular at a specific position, and the plane of the permanent magnet and the centerline of the main iron core can be perpendicular at a specific position.

[0009] Compared with the prior art, the beneficial effects of the present invention are as follows: The present invention is connected to multiple air turbines. When the multiple turbines are working, the powerful air pressure generated moves through the inclined pipes to the inclined plate structure. The high-pressure air from multiple directions acts on the surface of the inclined plate structure. Under the action of the high-pressure air, the multiple ring arrays of inclined plate structures generate a tendency to move in the same direction. This tendency to move in the same direction then drives the rotating column to rotate. At the same time, current is connected. According to the electromagnetic principle and the principle of like poles repelling and unlike poles attracting, the main iron core and permanent magnet generate the same magnetic poles at opposite end faces. At this time, under the action of electromagnetic effect, the rotational torque intensity is further increased. Driven by wind power, the rotating column rotates with strong rotational inertia. Each time it rotates to a specific position, the electromagnetic force can further enhance the rotational inertia, thereby optimizing the rotational pressurization effect and providing a wider range of pressurization. Attached Figure Description

[0010] Figure 1 This is a full cross-sectional structural diagram of an electric hybrid rotary booster device according to the present invention; Figure 2 This is a top view schematic diagram of an electric hybrid rotary booster device according to the present invention; In the diagram: 1, bottom mounting base; 2, column mounting base; 3, main column shell; 4, main component mounting hole; 5, main bearing; 6, rotating column; 7, annular protrusion structure; 8, inclined pipe; 9, pipe docking port; 10, inclined plate structure; 11, main iron core; 12, main coil; 13, main wire; 14, permanent magnet; 15, main protrusion structure; 16, main rotating column; 17, main connecting flange. Detailed Implementation

[0011] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0012] Please see Figure 1-2An embodiment of the present invention includes a bottom mounting base 1 and a rotating column 6. Two opposing column mounting bases 2 are mounted on the upper surface of the bottom mounting base 1. A main column shell 3 is fixed between the tops of the two column mounting bases 2. A main component mounting hole 4 is provided at the center of the interior of the main column shell 3. An integral annular protrusion structure 7 is provided at the center of the circumferential side of the rotating column 6. The two edges of the annular protrusion structure 7 are mounted on the inner wall of the center of the main component mounting hole 4 via a main bearing 5. Multiple annular array-type inclined plate structures 10 are provided on the two annular sides of the annular protrusion structure 7, each inclined plate structure 10 being an inclined surface structure. Multiple annular array-type main protrusion structures 1 are provided in the middle of the circumferential side of the main column shell 3. 5. Each of the main protrusion structures 15 has a main iron core 11 inside, and a main coil 12 is sleeved on the side of each main iron core 11. A main wire 13 is installed at the power input end of each main coil 12. The annular protrusion structure 7 has a plurality of annular array permanent magnets 14 inside, and the ends of the permanent magnets 14 and the main iron cores 11 are both inclined structures with the same slope. The main column shell 3 has a plurality of inclined pipes 8 connecting its outer and inner circular sides inside. Each inclined pipe 8 has a pipe docking port 9 at the end facing the outer circular side. A main rotating column 16 is fixed at the center of one end face of the rotating column 6, and a main connecting flange 17 is installed at the end of the main rotating column 16.

[0013] The angle between the plane of the inclined plate structure 10 and the virtual line of the inclined plate structure 10 pointing to the center line of the rotating cylinder 6 is an acute angle.

[0014] The angle between the plane of the permanent magnet 14 and the virtual line pointing to the center line of the rotating cylinder 6 is an acute angle.

[0015] The inclined plate structure 10 and the permanent magnet 14 are inclined in the same direction.

[0016] The centerline of the inclined pipe 8 and the plane of the inclined plate structure 10 can be perpendicular at a specific position, and the plane of the permanent magnet 14 and the centerline of the main iron core 11 can be perpendicular at a specific position.

[0017] Specific usage: In this invention, each pipe docking port 9 is connected to an air turbine via a pipe, and multiple main guide lines 13 are fixedly connected to the power output terminal of a current controller. Then, the air turbine is made to work, and the powerful air pressure generated moves through the inclined pipe 8 to the inclined plate structure 10. The high-pressure air from multiple directions acts on the surface of the inclined plate structure 10. Under the action of the high-pressure air, the multiple ring arrays of inclined plate structures 10 generate a tendency to move in the same direction. This tendency to move in the same direction then drives the rotating column 6 to rotate. At the same time, current is connected. According to the electromagnetic principle and the principle of like poles repelling and unlike poles attracting, the main iron core 11 and the permanent magnet 14 generate the same magnetic poles on opposite end faces. At this time, under the action of electromagnetic effect, the rotational torque intensity is further increased. Driven by wind power, the rotating column rotates with strong rotational inertia. Each time it rotates to a specific position, the electromagnetic force can further enhance the rotational inertia, thereby optimizing the rotational pressurization effect.

[0018] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. An electric hybrid power rotary assist device, comprising a bottom mounting base plate (1) and a rotating column (6), characterized in that: Two opposing column mounting bases (2) are mounted on the upper surface of the bottom mounting base (1). A main column shell (3) is fixed between the tops of the two column mounting bases (2). The main column shell (3) has a main component mounting hole (4) at its center. The rotating column (6) has an integrated annular protrusion structure (7) at its center on its circumferential side. The two edges of the annular protrusion structure (7) are mounted on the inner wall of the center of the main component mounting hole (4) via a main bearing (5). The two annular sides of the annular protrusion structure (7) have multiple annular array-type inclined plate structures (10). Each inclined plate structure (10) is an inclined surface structure. The main column shell (3) has multiple annular array-type main protrusion structures (15) in the middle of its circumferential side. The interior of each main protrusion structure (15) Each main iron core (11) is placed in a main iron core (11), and a main coil (12) is sleeved on the side of each main iron core (11). A main wire (13) is installed at the power input end of each main coil (12). The annular protrusion structure (7) is provided with a plurality of annular array permanent magnets (14), and the ends of the permanent magnets (14) and the main iron cores (11) are both inclined structures, and the slopes of the ends of the permanent magnets (14) and the main iron cores (11) are the same. The main column shell (3) is provided with a plurality of inclined pipes (8) connecting its outer and inner circular sides. Each inclined pipe (8) is provided with a pipe docking port (9) at the end facing the outer circular side. A main rotating column (16) is fixed at the center of one end face of the rotating column (6), and a main connecting flange (17) is installed at the end of the main rotating column (16).

2. The electric hybrid rotary booster device according to claim 1, characterized in that: The angle between the plane of the inclined plate structure (10) and the virtual line of the inclined plate structure (10) pointing to the center line of the rotating cylinder (6) is an acute angle.

3. The electric hybrid rotary booster device according to claim 1, characterized in that: The angle between the plane of the permanent magnet (14) and the virtual line pointing to the center line of the rotating cylinder (6) is an acute angle.

4. The electric hybrid rotary booster device according to claim 1, characterized in that: The inclined plate structure (10) and the permanent magnet (14) are in the same direction of inclination.

5. The electric hybrid rotary booster device according to claim 1, characterized in that: The centerline of the inclined pipe (8) and the plane of the inclined plate structure (10) can be perpendicular at a specific position, and the plane of the permanent magnet (14) and the centerline of the main iron core (11) can be perpendicular at a specific position.

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