Centrifugal mechanical power augmentation machine

By using a centrifugal mechanical power enhancer, and through the cooperation of the iron-throwing section and the gear disc, combined with the precise control of the electrical control cabinet, the problems of high energy loss and poor load adaptability of traditional power enhancement devices are solved, achieving efficient and stable power output and reducing maintenance costs.

CN224401305UActive Publication Date: 2026-06-23李明波

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
李明波
Filing Date
2025-06-27
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional power enhancement devices are complex in structure, have high energy loss and large size, making them difficult to adapt to load changes, resulting in low power conversion efficiency, poor stability and high maintenance costs.

Method used

It adopts a centrifugal mechanical power enhancer, which enhances power through the cooperation of the iron-throwing part and the gear disc. The electrical control cabinet provides precise control, adapts to different loads, and has strong stability.

Benefits of technology

It increases power output by 30%-50%, achieves precise control and adaptive adjustment, reduces maintenance costs, and improves the operational stability and reliability of the equipment.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This utility model relates to the field of power machinery technology and discloses a centrifugal mechanical power enhancer, including a support frame with a symmetrical support structure. One end is fixed with a reinforcing part, and the other end is rotatably connected to a second gear disk. The middle section supports a drive device. The drive device, using a motor structure, is located at the lower part of the support frame and is connected to the drive shaft via a chain to provide initial rotational power. The reinforcing part, the core power enhancement unit, includes: a first gear disk, coaxially connected to a connecting shaft, with an inner gear ring meshing with a drive gear, and circumferentially distributed mounting positions for the iron-throwing parts on the outer side; a positioning disk, coaxially arranged with the gear disk and maintaining a distance, rotatably connected to the support frame via bearings, providing a reaction force fulcrum for the iron-throwing parts; and three symmetrically arranged iron-throwing parts, each containing a 24 kg iron-throwing body. This utility model features a compact structure, efficient transmission, and enhanced power through the cooperation of the iron-throwing parts and gear disks. The electrical control cabinet allows for precise adjustment, adapting to different loads and exhibiting strong stability.
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Description

Technical Field

[0001] This utility model relates to the field of power machinery technology, and in particular to a centrifugal mechanical power enhancement machine. Background Technology

[0002] In various industrial production and power application scenarios, the efficient operation of power equipment is crucial. Traditional power transmission and enhancement methods have many limitations. For example, some common power enhancement devices have complex structures and significant energy losses during operation, resulting in low overall power conversion efficiency. Taking some traditional mechanical superchargers as an example, their gear transmission and other structures consume a lot of energy due to friction between components when transmitting power. Moreover, these devices are usually bulky and occupy a lot of space, which is not conducive to compact layout and integrated design.

[0003] Furthermore, existing power boosting equipment performs poorly in adapting to different working conditions. When the workload changes, many devices struggle to quickly and accurately adjust their output power, failing to meet diverse operational requirements in practice. For example, in scenarios requiring frequent start-stop operations or significant load variations, traditional power boosting equipment often cannot respond promptly, impacting work efficiency and equipment stability. Moreover, some traditional equipment is prone to failure after long-term operation, resulting in high maintenance costs, which also limits its application in fields with high requirements for equipment stability and low maintenance costs.

[0004] Therefore, those skilled in the art have provided centrifugal mechanical power enhancement machines to solve the problems mentioned in the background art. Utility Model Content

[0005] The purpose of this invention is to address the shortcomings of existing technologies by proposing a centrifugal mechanical power enhancer. This centrifugal power enhancer has a compact structure, high transmission efficiency, and enhances power through the combination of the iron-throwing part and gear disc. The electrical control cabinet can precisely adjust the power, adapt to different loads, and has strong stability.

[0006] To achieve the above objectives, the present invention provides the following technical solution:

[0007] Centrifugal mechanical power enhancer, including:

[0008] The bracket has a symmetrical support structure, with a reinforcing part fixed at one end and a gear disk rotatably connected at the other end, and the drive equipment is supported in the middle.

[0009] The drive unit, which adopts a motor structure, is located at the bottom of the bracket and is connected to the drive shaft via a chain to provide initial rotational power.

[0010] The enhancement section, the core power enhancement unit, includes:

[0011] Gear disk one, coaxially connected to the connecting shaft, inner gear ring meshes with the drive gear, and outer circumferentially distributed mounting positions for the iron-throwing parts;

[0012] The positioning plate, which is coaxially mounted with the gear plate and maintains a distance from it, is rotatably connected to the bracket via a bearing, providing a fulcrum for the iron-throwing section;

[0013] The weight-slinging section consists of three symmetrically arranged sets, each containing a 24 kg weight-slinging body, which dynamically coordinates with the gear disc and positioning disc via a V-shaped support frame.

[0014] Transmission system:

[0015] Gear disk two has the same structure as gear disk one, and is rotatably connected to the bracket via a drive shaft;

[0016] The transmission gear meshes with the inner side of the gear disc and is coaxially connected to the power equipment to enhance power output.

[0017] The connecting shaft and the drive shaft are connected by a large gear, a small gear, and a chain to form a speed reduction transmission.

[0018] The electrical control cabinet is integrated into the support drive equipment side, and controls the start and stop of the drive equipment and speed adjustment through circuitry.

[0019] Furthermore, both gear disk one and gear disk two are coaxially composed of a gear ring and a disk sleeve. The inner diameter of the gear ring meshes with the drive gear and the outer diameter of the disk sleeve is used to install the iron-throwing part.

[0020] Furthermore, one end of the connecting shaft extends into the center hole of the disc sleeve, and coaxial power transmission is achieved through a key connection.

[0021] Furthermore, the drive shaft passes through the non-gear ring side of the disc sleeve and is fixed to the bracket via a deep groove ball bearing seat to ensure coaxiality of the transmission.

[0022] Furthermore, the V-shaped support frame of the iron-throwing part has a bending angle of 135°, and the bending point is rotatably connected to the disc sleeve through a pin shaft, while the limiting block rolls against the outer edge of the positioning disc.

[0023] Furthermore, the three sets of iron-throwing parts are evenly distributed around the disc sleeve at 120° circumference, forming a three-in-one centrifugal force balance structure.

[0024] Furthermore, the large gear on the connecting shaft has a diameter of 570mm, and the small gear on the transmission shaft has a diameter of 85mm, with a transmission ratio of 4.3:1 to achieve speed reduction and torque increase.

[0025] Furthermore, the distance between the gear disk and the positioning disk is designed to meet the 45° eccentric lever arm requirement of the iron-throwing part, forming an eccentric external force working state.

[0026] Furthermore, the electrical control cabinet integrates a speed sensor interface, which can monitor the drive shaft speed in real time and provide feedback for adjustment.

[0027] Furthermore, a torque sensor is installed at the output end of the power equipment to achieve adaptive load adjustment in conjunction with the electrical control cabinet.

[0028] This utility model has the following beneficial effects:

[0029] 1. This utility model proposes a centrifugal mechanical power enhancer. Through a unique structural design, this centrifugal mechanical power enhancer achieves a highly efficient power enhancement effect. The coordinated operation of the gear disk, positioning disk, and iron-throwing part in the enhancement section utilizes the principle of centrifugal force. When the gear disk rotates at high speed, the iron-throwing part generates a strong external force under the action of centrifugal force, providing core support for power enhancement. Combined with the reduction transmission system consisting of a large gear, a small gear, and a chain between the connecting shaft and the transmission shaft, speed reduction and torque amplification are achieved, effectively amplifying the initial rotational power and providing stronger output power to the power equipment. Compared with traditional power enhancement devices, this invention can significantly improve the output torque under the same input power conditions. For example, in some practical application scenarios, it can increase the power output by 30%-50%, greatly enhancing the working efficiency of the power equipment and meeting the needs of various working scenarios with high power requirements.

[0030] 2. The centrifugal mechanical power enhancer proposed in this utility model features an integrated electrical control cabinet design that provides precise control capabilities. The control cabinet not only controls the start and stop of the drive equipment but also monitors the drive shaft speed in real time via a speed sensor interface and adjusts it based on set parameters. Simultaneously, a torque sensor at the power equipment output end, working in conjunction with the control cabinet, enables adaptive load adjustment. When the workload changes, the system responds quickly, automatically adjusting the drive equipment speed and output torque to maintain the power enhancer in a stable operating state. This precise control and adaptive adjustment not only improves the operational stability of the power enhancer but also effectively extends its service life, reduces damage caused by overload or sudden load changes, lowers maintenance costs, and enhances reliability and availability. Attached Figure Description

[0031] Figure 1 This is a schematic diagram of the structure of the centrifugal mechanical power enhancement machine of this utility model. Figure 1 ;

[0032] Figure 2 yes Figure 1 A magnified view of a section at point A in the middle;

[0033] Figure 3 This is a schematic diagram of the structure of the centrifugal mechanical power enhancement machine of this utility model. Figure 2 ;

[0034] Figure 4 This is a schematic diagram of the structure of the centrifugal mechanical power enhancement machine of this utility model. Figure 3 ;

[0035] Figure 5 This is a top view of the centrifugal mechanical power enhancer of this utility model;

[0036] Figure 6 This is a front view of the centrifugal mechanical power enhancer of this utility model;

[0037] Figure 7 This is a schematic diagram of the reinforcing section in the centrifugal mechanical power enhancer of this utility model. Figure 1 ;

[0038] Figure 8 This is a schematic diagram of the reinforcing section in the centrifugal mechanical power enhancer of this utility model. Figure 2 ;

[0039] Figure 9 This is a schematic diagram of the reinforcing section in the centrifugal mechanical power enhancer of this utility model. Figure 3 .

[0040] Legend:

[0041] 1. Bracket; 2. Drive unit; 3. Reinforcing part; 31. Gear disk one; 311. Gear ring; 312. Disc sleeve; 32. Positioning disk; 33. Iron throwing part; 331. Iron throwing body; 332. Support frame; 333. Limiting block; 34. Connecting shaft; 35. Drive gear; 36. Drive shaft; 4. Gear disk two; 5. Transmission shaft; 6. Transmission gear; 7. Power equipment; 8. Electrical control cabinet. Detailed Implementation

[0042] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0043] Reference Figure 1-9 An embodiment of this utility model is provided: a centrifugal mechanical power enhancer, comprising: a support 1, which has a symmetrical support structure, with a reinforcing part 3 fixed at one end and a gear disk 4 rotatably connected at the other end, and a drive device 2 supported in the middle; the drive device 2 adopts a motor structure, is located at the lower part of the support 1, and is connected to the drive shaft 36 through a chain to provide initial rotational power;

[0044] Specifically, the support frame 1 adopts a symmetrical support structure, with the reinforcing part 3 firmly fixed at one end. This connection method ensures the stability of the reinforcing part 3 during operation and can effectively resist the vibration and stress generated by high-speed rotation. The other end is rotatably connected to the gear disk 4, providing a supporting foundation for the smooth rotation of the gear disk 4 and ensuring the stable operation of the transmission system. The drive device 2 is carried in the middle. The reasonable layout design makes the entire power enhancement machine structure compact, with each component working together, reducing unnecessary space occupation and improving the integration of the equipment. This symmetrical support structure design, while ensuring structural strength, can also effectively balance the forces generated during equipment operation, improve the stability and reliability of the equipment, and extend the service life of the equipment. The drive device 2 is a motor structure located at the lower part of the support frame 1. When the motor is powered on, the rotor of the motor begins to rotate, generating initial rotational power. This power is transmitted to the drive shaft 36 through a chain. Chain drive has the advantages of high transmission efficiency and the ability to adapt to a large transmission ratio, and can stably transmit the power of the motor to the subsequent components. This drive method can quickly respond to the control commands issued by the electrical control cabinet 8, accurately adjust the speed, and provide a stable and adjustable initial power source for the entire power enhancement machine. Driven by an electric motor, the power output can be flexibly controlled to meet the power requirements under different working conditions. Compared with some other drive methods, it has better controllability and stability.

[0045] The reinforcement unit 3, the core power reinforcement unit, includes: a gear disk 31, a coaxially connected shaft 34, an inner gear ring 311 meshing with a drive gear 35, and mounting positions for the iron-throwing parts 33 evenly distributed on the outer circumferential direction; a positioning disk 32, coaxially arranged with the gear disk 31 and maintaining a distance, rotatably connected to the bracket 1 through a bearing, providing a reaction force fulcrum for the iron-throwing parts 33; and three symmetrically arranged iron-throwing parts 33, each containing a 24 kg iron-throwing body 331, dynamically cooperating with the gear disk 31 and the positioning disk 32 through a V-shaped support frame 332.

[0046] Specifically, gear disc 31 is coaxially sleeved with connecting shaft 34, and inner gear ring 311 meshes with drive gear 35. When drive gear 35 rotates under the drive of drive shaft 36, it drives gear ring 311, thereby causing gear disc 31 to rotate synchronously around connecting shaft 34. Mounting positions for the iron-slinging parts 33 are evenly distributed on the outer circumference. This design allows gear disc 31 to fully utilize the principle of centrifugal force during rotation. As the rotational speed of gear disc 31 increases, the iron-slinging parts 33 generate a powerful outward swinging force under centrifugal force, providing crucial support for power enhancement. Through the meshing transmission between gear ring 311 and drive gear 35, power transmission is precise and efficient, ensuring stable high-speed operation of gear disc 31 and providing a stable foundation for the effective functioning of iron-slinging parts 33.

[0047] The positioning disk 32 is coaxially arranged with the gear disk 31 at a distance, and is rotatably connected to the bracket 1 via bearings. When the iron-throwing part 33 is thrown outward under the centrifugal force generated by the rotation of the gear disk 31, the positioning disk 32 provides a fulcrum for the reaction force of the iron-throwing part 33. The iron-throwing part 33 dynamically cooperates with the positioning disk 32 through the V-shaped support frame 332. During the throwing process, the positioning disk 32 bears the reaction force from the iron-throwing part 33, ensuring that the iron-throwing part 33 can stably generate eccentric force, which is then converted into additional assistance for the rotation of the gear disk 31, achieving effective power enhancement. At the same time, the bearing connection to the bracket 1 allows the positioning disk 32 to rotate smoothly even under the reaction force, reducing energy loss and improving the efficiency of power enhancement.

[0048] The iron-throwing unit 33 consists of three symmetrically arranged groups, each containing a 24 kg iron-throwing body 331. These groups are dynamically coordinated with the gear disc 31 and positioning disc 32 via a V-shaped support frame 332. When the gear disc 31 rotates at high speed, the iron-throwing body 331, under centrifugal force, is thrown outwards around its connection point with the gear disc 31 via the V-shaped support frame 332. The V-shaped support frame 332 has a bending angle of 135°. This angle design allows the iron-throwing unit 33 to generate a suitable eccentric force during rotation, effectively converting it into assistance for the rotation of the gear disc 31. The bend is rotatably connected to the disc sleeve 312 via a pin, ensuring that the iron-throwing unit 33 can flexibly adjust its position according to changes in centrifugal force. The limiting block 333 rolls against the outer edge of the positioning disc 32, limiting excessive swinging of the iron-throwing unit 33 and reducing frictional resistance during swinging, ensuring stable operation of the iron-throwing unit 33. The three sets of iron-throwing sections 33 and 312 are evenly distributed around the circumference at 120°, forming a three-in-one centrifugal force balancing structure. While generating a powerful power enhancement effect, it ensures the balance and stability of the entire system during high-speed rotation, reducing equipment vibration and wear caused by unbalanced forces.

[0049] Transmission system: Gear disk 2 4, with the same structure as gear disk 1 31, is rotatably connected to bracket 1 via transmission shaft 5; transmission gear 6 meshes inside gear disk 2 4 and is coaxially connected to power equipment 7 to output enhanced power; connecting shaft 34 and transmission shaft 5 form a speed reduction transmission through large gear, small gear and chain;

[0050] Specifically, gear disk 2 4 has the same structure as gear disk 1 31, and is rotatably connected to bracket 1 via drive shaft 5. When connecting shaft 34 transmits power to drive shaft 5 through a reduction transmission system, drive shaft 5 drives gear disk 2 4 to rotate. The gear ring 311 on the inner side of gear disk 2 4 meshes with the transmission gear 6, transmitting the enhanced power to power device 7. This structural design, identical to gear disk 1 31, ensures the consistency and stability of the entire transmission system during power transmission, enabling power to be efficiently transmitted from reinforcement part 3 to power device 7, thereby enhancing the output power of power device 7.

[0051] The transmission gear 6 meshes with the inner side of the gear disk 4 and is coaxially connected to the power device 7 to output enhanced power. When the gear disk 4 rotates, the inner gear ring 311 drives the transmission gear 6 to rotate, and the transmission gear 6 then transmits the power to the power device 7 coaxially connected to it. The transmission gear 6 plays a key role in power connection in the entire transmission system. Through precise gear meshing design, it can ensure the accuracy and efficiency of power transmission, and stably deliver the power enhanced by the reinforcement part 3 to the power device 7, meeting the power device 7's demand for strong power.

[0052] The connecting shaft 34 and the drive shaft 5 form a speed reduction transmission via a large gear, a small gear, and a chain. The large gear on the connecting shaft 34 has a diameter of 570mm, and the small gear on the drive shaft 5 has a diameter of 85mm, with a transmission ratio of 4.3:1 to achieve speed reduction and torque increase. When the connecting shaft 34 rotates at high speed driven by the gear disc 31, the large gear rotates accordingly, driving the small gear to rotate via the chain. Because the diameter of the large gear is much larger than that of the small gear, the speed is reduced during transmission, while the torque is increased according to the inverse relationship between torque and speed. This speed reduction and torque increase design can convert the high-speed, low-torque power generated by the reinforcing section 3 into low-speed, high-torque power suitable for the needs of the power equipment 7, improving power utilization efficiency and better meeting the power requirements of the power equipment 7 under different operating conditions.

[0053] The electrical control cabinet 8 is integrated on the side of the drive device 2 of the bracket 1. It controls the start and stop and speed adjustment of the drive device 2 through the circuit. The electrical control cabinet 8 integrates a speed sensor interface, which can monitor the speed of the drive shaft 36 in real time and provide feedback for adjustment. The output end of the power device 7 is equipped with a torque sensor, which works with the electrical control cabinet 8 to achieve adaptive load adjustment.

[0054] Specifically, the electrical control cabinet 8 is integrated on the drive device 2 side of the bracket 1, controlling the start / stop and speed adjustment of the drive device 2 via circuitry. It integrates a speed sensor interface, which can monitor the speed of the drive shaft 36 in real time and provide feedback for adjustment. The speed sensor accurately measures the real-time speed of the drive shaft 36 and transmits the data to the control unit within the electrical control cabinet 8. The control unit precisely adjusts the speed of the drive device 2 according to preset speed parameters and actual working requirements. For example, when the load on the power device 7 increases, the electrical control cabinet 8 reduces the speed of the drive device 2 to decrease system energy consumption and prevent equipment overload; when the load decreases, it increases the speed of the drive device 2 to improve power output efficiency. A torque sensor is installed at the output end of the power device 7, working with the electrical control cabinet 8 to achieve adaptive load adjustment. The torque sensor monitors the output torque of the power device 7 in real time, and when the torque changes, it feeds the signal back to the electrical control cabinet 8. The electrical control cabinet 8 adjusts the working state of the drive device 2 based on the feedback signal, ensuring that the entire power enhancement machine operates stably and efficiently under different load conditions, improving the intelligence and adaptability of the equipment.

[0055] Both gear disc 1 (31) and gear disc 2 (4) are coaxially composed of a gear ring 311 and a disc sleeve 312. The inner diameter of the gear ring 311 meshes with the drive gear 35 and the transmission gear 6, ensuring efficient power transmission. The outer diameter of the disc sleeve 312 is used to mount the iron-throwing part 33, providing a mounting base for the iron-throwing part 33 and ensuring its stability during rotation. This structural design allows the gear discs to effectively work in conjunction with the iron-throwing part 33 while transmitting power, leveraging centrifugal force to enhance power. Furthermore, the compact structure reduces unnecessary space occupation and the number of components, improving the reliability and maintainability of the equipment.

[0056] One end of the connecting shaft 34 extends into the center hole of the disc sleeve 312, and coaxial power transmission is achieved through a key connection. The key connection ensures accurate and reliable torque transmission between the connecting shaft 34 and the disc sleeve 312, prevents relative slippage during high-speed rotation, and ensures that the rotation of the gear disc 31 can stably drive the connecting shaft 34 to rotate, thereby transmitting power to the subsequent transmission system and providing a stable power transmission path for the entire power enhancement process.

[0057] The drive shaft 5 passes through the non-gear ring 311 side of the disc sleeve 312 and is fixed to the bracket 1 by a deep groove ball bearing housing to ensure coaxiality of the transmission. The deep groove ball bearing housing can provide stable support for the drive shaft 5, reduce the radial and axial runout of the drive shaft 5 during rotation, ensure the coaxiality of the drive shaft 5, the gear disc 4, and the entire transmission system, improve the efficiency and stability of power transmission, and reduce energy loss and equipment wear caused by poor coaxiality.

[0058] The V-shaped support frame 332 of the iron-throwing section 33 has a bending angle of 135°. The bend is rotatably connected to the disc sleeve 312 via a pin. The limiting block 333 rolls against the outer edge of the positioning disc 32. The three sets of iron-throwing sections 33 are evenly distributed around the disc sleeve 312 at 120° circumference. The 135° bending angle is carefully designed so that the eccentric force generated by the iron-throwing section 33 under centrifugal force can be effectively converted into assistance for the rotation of the gear disc 31. The pin connection ensures the flexibility of the iron-throwing section 33's rotation, while the rolling contact between the limiting block 333 and the positioning disc 32 restricts the range of motion of the iron-throwing section 33 and reduces friction. The evenly distributed 120° circumferential layout forms a stable centrifugal force balance structure. During high-speed rotation, the centrifugal forces generated by each iron-throwing section 33 are balanced, reducing equipment vibration and improving the stability and reliability of equipment operation.

[0059] The distance between gear disk 31 and positioning disk 32 is designed to meet the 45° eccentric lever arm requirement of the iron-throwing section 33, forming an eccentric external force working state. This distance design ensures that the iron-throwing section 33 generates an eccentric lever arm of appropriate length under the action of centrifugal force, so that the eccentric force can be effectively converted into an external force for the rotation of gear disk 31, enhancing the power output effect. Through precise distance design, the working state of the iron-throwing section 33 is optimized, and the overall performance of the power enhancement machine is improved.

[0060] Working principle: The drive device 2, as the power source of the entire power enhancement machine, adopts an electric motor structure and is located at the lower part of the support 1. When the equipment starts, the drive device 2 is powered on and generates initial rotational power. This power is transmitted to the drive shaft 36 through a chain, and the drive shaft 36 then drives the drive gear 35 connected to it to rotate.

[0061] The drive gear 35 meshes with the gear ring 311 on the inner side of the gear disk 31, thereby driving the gear disk 31 to rotate coaxially. The gear disk 31 is coaxially sleeved with the connecting shaft 34, so that the connecting shaft 34 rotates synchronously with the gear disk 31. During the rotation of the gear disk 31, the circumferentially distributed iron-throwing parts 33 on its outer side are thrown outward under the action of centrifugal force. The iron-throwing parts 33 are dynamically coordinated with the gear disk 31 and the positioning plate 32 through the V-shaped support frame 332. The positioning plate 32 provides a reaction force fulcrum for the iron-throwing parts 33, so that the eccentric force generated by the iron-throwing parts 33 under the action of centrifugal force can be converted into additional assistance for the rotation of the gear disk 31, realizing the initial enhancement of power.

[0062] The rotation of connecting shaft 34 is transmitted to drive shaft 5 through a reduction transmission system consisting of a large gear, a small gear, and a chain. Because the diameters of the large gear on connecting shaft 34 and the small gear on drive shaft 5 differ (e.g., the large gear is 570mm in diameter and the small gear is 85mm in diameter), with a transmission ratio of 4.3:1, speed reduction and torque increase are achieved during transmission, further enhancing power output. Drive shaft 5 drives the connected gear disc 2 4 to rotate. Gear disc 2 4 has the same structure as gear disc 1 31, and its inner gear ring 311 meshes with drive gear 6. Drive gear 6 transmits the enhanced power to power equipment 7, thereby increasing the output power of power equipment 7.

[0063] Throughout the entire operation, the electrical control cabinet 8 monitors the rotational speed of the drive shaft 36 in real time, and precisely adjusts the rotational speed of the drive device 2 based on the set operating parameters and the load status of the power equipment 7 fed back by the torque sensor. This ensures that the power enhancement machine can operate stably and efficiently under different working conditions, achieving effective power enhancement and precise control of the power equipment 7.

[0064] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A centrifugal mechanical power enhancer, characterized in that, include: The bracket (1) has a symmetrical support structure, with a reinforcing part (3) fixed at one end and a gear disk (4) rotatably connected at the other end, and the drive device (2) is carried in the middle. The drive device (2) adopts a motor structure and is located at the bottom of the bracket (1). It is connected to the drive shaft (36) via a chain to provide initial rotational power. Enhancement section (3), core power enhancement unit, including: Gear disk 1 (31), coaxially connected to connecting shaft (34), inner gear ring (311) meshes with drive gear (35), and outer circumferentially distributed iron-throwing parts (33) mounting positions; The positioning plate (32) is coaxially arranged with the gear plate (31) and maintains a distance from it. It is rotatably connected to the bracket (1) through a bearing, and provides a reaction force fulcrum for the iron-throwing part (33). The iron-throwing section (33) consists of three symmetrically arranged units, each containing a 24 kg iron-throwing body (331), which dynamically coordinates with the gear disc (31) and positioning disc (32) via a V-shaped support frame (332); Transmission system: Gear disk two (4) has the same structure as gear disk one (31) and is rotatably connected to bracket (1) via transmission shaft (5); The transmission gear (6) meshes with the inner side of the gear disk (4) and is coaxially connected to the power equipment (7) to output enhanced power; The connecting shaft (34) and the transmission shaft (5) form a speed reduction transmission through a large gear, a small gear and a chain; The electrical control cabinet (8) is integrated on the side of the bracket (1) and the drive equipment (2), and controls the start and stop of the drive equipment (2) and the speed adjustment through the circuit.

2. The centrifugal mechanical power enhancer according to claim 1, characterized in that: Both the first gear disk (31) and the second gear disk (4) are coaxially composed of a gear ring (311) and a disk sleeve (312). The inner diameter of the gear ring (311) meshes with the drive gear (35) and the transmission gear (6). The outer diameter of the disk sleeve (312) is used to install the iron-slinging part (33).

3. The centrifugal mechanical power enhancer according to claim 2, characterized in that: One end of the connecting shaft (34) extends into the center hole of the disc sleeve (312) and is connected by a key to achieve coaxial power transmission.

4. The centrifugal mechanical power enhancer according to claim 2, characterized in that: The drive shaft (5) passes through the non-gear ring (311) side of the disc sleeve (312) and is fixed to the bracket (1) by a deep groove ball bearing seat to ensure the coaxiality of the transmission.

5. The centrifugal mechanical power enhancer according to claim 2, characterized in that: The V-shaped support frame (332) of the iron-throwing part (33) has a bending angle of 135°. The bending point is rotatably connected to the disc sleeve (312) through a pin shaft. The limiting block (333) rolls against the outer edge of the positioning disc (32).

6. The centrifugal mechanical power enhancer according to claim 5, characterized in that: The three sets of iron-throwing parts (33) are evenly distributed around the disc sleeve (312) at 120° circumference, forming a three-in-one centrifugal force balance structure.

7. The centrifugal mechanical power enhancer according to claim 1, characterized in that: The connecting shaft (34) has a large gear with a diameter of 570mm and a small gear with a diameter of 85mm on the transmission shaft (5). The transmission ratio of 4.3:1 achieves speed reduction and torque increase.

8. The centrifugal mechanical power enhancer according to claim 1, characterized in that: The distance between the gear disk (31) and the positioning disk (32) is designed to meet the 45° eccentric lever arm requirement of the iron-throwing part (33), forming an eccentric external force working state.

9. The centrifugal mechanical power enhancer according to claim 1, characterized in that: The electrical control cabinet (8) integrates a speed sensor interface, which can monitor the speed of the drive shaft (36) in real time and provide feedback for adjustment.

10. The centrifugal mechanical power enhancer according to claim 1, characterized in that: The power equipment (7) is equipped with a torque sensor at its output end, which works in conjunction with the electrical control cabinet (8) to achieve adaptive load adjustment.