A speed multiplication transmission system

By designing rotatably connected input and output parts in the transmission system and configuring the transmission part, the problems of complex structure and low efficiency of traditional transmission systems are solved, achieving a highly efficient and flexible speed multiplication effect, and reducing cost and friction loss.

CN117307686BActive Publication Date: 2026-06-23CHONGQING KECR TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
CHONGQING KECR TECH CO LTD
Filing Date
2023-11-17
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Traditional transmission systems suffer from problems such as complex structure, high manufacturing and maintenance costs, low transmission efficiency, and poor overall performance due to the addition of extra mechanical components to adjust the output.

Method used

Design a speed multiplier transmission system by setting an input and an output part on the mounting base so that they can be rotatably connected, and configuring a transmission part on the other side to realize the coordinated work of the input and output parts, reduce friction between mechanical components and simplify the structure.

Benefits of technology

It improves the flexibility and adjustability of the transmission system, reduces energy loss, increases transmission efficiency, reduces weight and volume, and lowers manufacturing and maintenance costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the technical field of rotating speed transmission, and discloses a rotating speed multiplication transmission system which comprises a mounting base, an input part and an output part arranged on one side of the mounting base, wherein the input part and the output part are rotatably connected with the mounting base respectively, a transmission part arranged on the side, away from the mounting base, of the input part, one end of the transmission part being connected with the input part, the other end of the transmission part being connected with the output part, and the transmission part being used for driving the output part to move synchronously with the input part. The input part, the output part and the transmission part are ingeniously arranged on the mounting base, and the rotatable connection is adopted, so that the transmission part is driven by the input part when moving in the input direction, the movement speed of the output part is effectively improved, and the high-efficiency rotating speed multiplication effect is realized.
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Description

Technical Field

[0001] This invention relates to the field of speed transmission technology, and in particular to a speed multiplication transmission system. Background Technology

[0002] Transmission systems are widely used in various mechanical applications to efficiently transmit power and motion. In some applications, it is necessary to adjust the speed of the output components to meet specific operational requirements.

[0003] Currently, traditional transmission systems typically require additional mechanical components to adjust output, which not only complicates the system and increases manufacturing and maintenance costs but also potentially introduces more potential points of failure. Furthermore, this complex structure adds weight and size, hindering applications requiring lightweight and compact designs. Simultaneously, these additional mechanical components cause friction and energy loss during power transmission, leading to a decrease in overall transmission system efficiency. In applications requiring frequent adjustments to output speed, each transmission link may accumulate energy losses, further impacting the overall performance of the transmission system.

[0004] Therefore, there is an urgent need to invent a transmission system that increases the rotational speed, in order to solve many problems caused by the need to adjust the output in traditional transmission systems by adding additional mechanical components. Summary of the Invention

[0005] The purpose of this invention is to provide a speed multiplication transmission system, which aims to solve the problems of structural complexity, high manufacturing and maintenance costs, low transmission efficiency, and poor overall transmission performance caused by the need to add additional mechanical components to adjust the output in traditional transmission systems.

[0006] On one hand, an embodiment of the present invention provides a speed multiplication transmission system, comprising:

[0007] Mounting base;

[0008] An input section and an output section are disposed on one side of the mounting base, and the input section and the output section are rotatably connected to the mounting base respectively;

[0009] A transmission unit is disposed on the side of the input unit away from the mounting base. One end of the transmission unit is connected to the input unit, and the other end of the transmission unit is connected to the output unit. The transmission unit is used to drive the output unit to move synchronously with the input unit.

[0010] Furthermore, the mounting base includes:

[0011] Base;

[0012] A mounting plate is disposed on the upper surface of the base, and the mounting plate is perpendicular to the base. Two first through holes are arranged side by side along the horizontal direction on one side wall of the mounting plate.

[0013] The mounting bearings are provided in two sets, and the two sets of mounting bearings are respectively located at both ends of the side of the mounting plate where the first through hole is opened. The mounting bearings are arranged corresponding to the first through hole and are fixedly connected to the mounting plate.

[0014] Furthermore, the output unit includes:

[0015] The first transmission disc is disposed on the side of the mounting plate away from the mounting bearing. The first transmission disc passes through the first through hole and the mounting bearing and is rotatably connected to the mounting bearing.

[0016] The first mounting hole is located on the side of the first transmission disk away from the mounting plate, and the first mounting hole is set along the axial direction of the first transmission disk.

[0017] Furthermore, the first transmission disc includes:

[0018] The first gear disk is disposed on the side of the mounting plate away from the mounting bearing;

[0019] A transmission gear is disposed on the side of the first gear disk away from the mounting plate. The transmission gear is connected to the first gear disk, and a second through hole is provided in the middle of the transmission gear.

[0020] A first drive shaft passes through a through hole in the first gear disc, a mounting bearing, and the drive gear, so that the first gear disc and the drive gear move synchronously.

[0021] Furthermore, the input unit includes:

[0022] The second gear disk is disposed on the side of the mounting plate away from the mounting bearing, and the second gear disk is arranged side by side with the first gear disk;

[0023] The second drive shaft has one end passing through the first through hole and rotatably connected to the mounting bearing, and the other end of the second drive shaft is fixedly connected to the middle of the second gear disk.

[0024] Furthermore, the transmission unit includes:

[0025] A drive gear is disposed on the side of the first gear disk away from the mounting plate. The drive gear passes through the first mounting hole and is connected to the first gear disk. The drive gear is rotatably connected to the transmission gear. The drive gear is used to drive the transmission gear to rotate along the direction of movement of the drive gear.

[0026] A transmission rod assembly, one end of which is connected to the drive gear, and the other end of which is connected to the second gear disk, is used to drive the drive gear to move.

[0027] Furthermore, the transmission rod assembly includes:

[0028] A transmission rod, one end of which is connected to the drive gear, and the other end of which is connected to the second gear disk, wherein the end of the transmission rod connected to the drive gear is also provided with a sliding hole;

[0029] A fixing member passes through the sliding hole and is fixedly connected to the drive gear. The fixing member is used to fix the transmission rod and the drive gear.

[0030] Furthermore, the sliding hole is elongated.

[0031] Furthermore, an eccentric shaft is provided at the other end of the transmission rod. One end of the eccentric shaft is fixedly connected to the transmission rod, and the other end of the eccentric shaft is connected to the second gear disk.

[0032] Furthermore, the second gear disk is also provided with a second mounting hole, and the other end of the eccentric shaft passes through the second mounting hole and is connected to the second gear disk.

[0033] Compared with existing technologies, the speed multiplication transmission system of this invention offers the following advantages: By setting an input and output section on the mounting base, the input and output sections can rotate flexibly and are rotatably connected to the mounting base. Furthermore, a transmission section is configured on the other side of the mounting base, with one end connected to the input section and the other end connected to the output section. Through the coordinated work of the input and transmission sections, the output section is smoothly propelled in the input direction. The resulting advantages include improved flexibility and adjustability of the transmission system, enabling the overall transmission system to adapt more efficiently to different work requirements. Simultaneously, it reduces friction between mechanical components, thereby reducing energy loss and further improving the overall efficiency of the transmission system. In addition, the simplified structural design not only helps to reduce the weight and size of the transmission system but also effectively reduces manufacturing and maintenance costs. Attached Figure Description

[0034] Figure 1 This is a front view of a speed multiplication transmission system according to an embodiment of the present invention.

[0035] Figure 2 This is a cross-sectional schematic diagram of the input section in an embodiment of the present invention.

[0036] Figure 3 This is a cross-sectional schematic diagram of the output section in an embodiment of the present invention.

[0037] In the diagram, 110 is the base; 120 is the mounting plate; 130 is the mounting bearing; 210 is the second gear disc; 220 is the second drive shaft; 230 is the chain; 311 is the first gear disc; 312 is the transmission gear; 313 is the first drive shaft; 410 is the drive gear; 421 is the transmission rod; 422 is the fixing component; and 423 is the eccentric shaft. Detailed Implementation

[0038] The specific embodiments of the present invention will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and are not intended to limit the scope of the invention.

[0039] In the description of this application, it should be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this application.

[0040] The terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this application, unless otherwise stated, "a plurality of" means two or more.

[0041] In the description of this application, it should be noted that, unless otherwise expressly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection between two components. Those skilled in the art can understand the specific meaning of the above terms in this application based on the specific circumstances.

[0042] like Figure 1As shown, an embodiment of the present invention provides a speed multiplication transmission system, comprising: a mounting base, an input section, an output section, and a transmission section. The input section and the output section are disposed on one side of the mounting base and are rotatably connected to the mounting base, respectively; the transmission section is disposed on the side of the input section away from the mounting base, one end of the transmission section is connected to the input section, and the other end of the transmission section is connected to the output section, and the transmission section is used to drive the output section to move synchronously with the input section.

[0043] As can be seen, the speed multiplication transmission system in this embodiment consists of four main components: a mounting base, an input section, an output section, and a transmission section. First, the input and output sections are located on one side of the mounting base and are rotatably connected to it, providing flexibility and rotatability for the entire transmission system. Second, the transmission section is located on the opposite side of the input and output sections, away from the mounting base, with one end connected to the input section and the other end connected to the output section. This design allows the transmission section to effectively transmit power when the input section moves in the input direction, thereby driving the output section to move in the input direction and achieving a speed multiplication effect. Through ingenious layout and connection methods, the motion of the input section can be effectively transmitted to the output section, achieving speed multiplication during the transmission process. This innovative structural design has many advantages, including improved transmission system flexibility, simplified structure, reduced energy loss, and the potential to provide a more efficient and reliable transmission solution in mechanical applications.

[0044] Understandably, by placing the input and output sections on opposite sides of the mounting base and rotatably connecting them, a more flexible structural design is achieved, allowing the entire transmission system to move at different angles and directions, thus adapting to diverse working environments. Secondly, the placement of the transmission unit on the opposite side of the input and output sections, away from the mounting base, enables efficient transmission of motion from the input to the output, achieving a speed multiplication effect. This further improves the performance and efficiency of the transmission system, allowing for greater output power under the same input conditions. Furthermore, due to the ingenious structural layout, the transmission system reduces friction and energy loss during power transmission, contributing to improved overall energy efficiency. Simultaneously, by placing the input and output sections on the mounting base and positioning the transmission unit away from the base, the overall structure is simplified, reducing the weight and size of the transmission system. This provides a superior solution for applications requiring lightweight and compact design, such as mobile devices or space-constrained mechanical systems. Ultimately, this speed multiplication transmission system not only improves performance and efficiency but also possesses greater flexibility and portability, opening up new possibilities for various engineering applications.

[0045] Specifically, in some embodiments of the present invention, the mounting base includes: a base 110, a mounting plate 120, and a mounting bearing 130. The mounting plate 120 is disposed on the upper surface of the base 110, and the mounting plate 120 and the base 110 are arranged perpendicularly to each other. Two first through holes are arranged side-by-side in a horizontal direction on one side wall of the mounting plate 120. Two sets of mounting bearings 130 are provided, and the two sets of mounting bearings 130 are respectively located at both ends of the side of the mounting plate 120 where the first through holes are located. The mounting bearings 130 are correspondingly disposed to the first through holes and are fixedly connected to the mounting plate 120.

[0046] As can be seen, the mounting base in this embodiment consists of three main components: a base 110, a mounting plate 120, and mounting bearings 130. First, the base 110 serves as the foundation of the entire structure, with the mounting plate 120 mounted on its upper surface. The mounting plate 120 is tightly connected to the base 110 via a fixed connection, ensuring the stability and robustness of the entire base 110. Second, one side of the mounting plate 120 has two parallel first through holes, providing a fixed position and guidance for the installation of subsequent components. These two first through holes are located at both ends of the centerline of the mounting plate 120, helping to maintain symmetry and balance. Third, the mounting bearings 130 are divided into two groups, each installed on the side of the mounting plate 120 with a first through hole. The mounting bearings 130 are correspondingly positioned with the first through holes, achieving alignment and accurate positioning. By fixing the mounting bearings 130 to the mounting plate 120, a robust support structure is formed. This design not only simplifies the installation of the mounting bearings 130 but also provides reliable support and a rotational reference for subsequent mechanical components.

[0047] Understandably, by combining the base 110, mounting plate 120, and mounting bearing 130, a stable and reliable support foundation is formed, ensuring the structural robustness of the entire transmission system. The mounting plate 120 is fastened to the upper surface of the base 110, and this fixed connection ensures a tight fit between the base 110 and the mounting plate 120, providing a solid foundation for subsequent mechanical devices. Secondly, the design of the mounting plate 120 considers practicality, with two parallel first through holes on one side, positioned at both ends along the centerline of the mounting plate 120. This layout makes the mounting plate 120 symmetrical and balanced, providing convenient and accurate positioning points for subsequent assembly. The first through holes provide stable positioning and guidance for the mounting bearing 130, thereby simplifying the installation process and reducing the risk of errors. Furthermore, two sets of mounting bearings 130 are respectively installed at both ends of one side of the mounting plate 120, corresponding to the first through holes, and fixedly connected to the mounting plate 120. This structure ensures the accurate positioning of the mounting bearing 130, not only supporting and fixing rotating parts but also effectively transmitting and distributing mechanical loads, improving the stability and reliability of the entire transmission system. Finally, by combining the base 110, mounting plate 120, and mounting bearing 130, a robust, easy-to-assemble, and accurately positioned base 110 is achieved. This facilitates the construction of subsequent mechanical devices, reduces difficulties and errors in the assembly process, and effectively enhances the stability of the entire transmission system.

[0048] See Figure 3 As shown, in some embodiments of the present invention, the output section includes a first transmission disk and a first mounting hole. The first transmission disk is disposed on the side of the mounting plate 120 away from the mounting bearing 130, and the first transmission disk passes through the first through hole and the mounting bearing 130 and is rotatably connected to the mounting bearing 130; the first mounting hole is formed on the side of the first transmission disk away from the mounting plate 120, and the first mounting hole is arranged along the axial direction of the first transmission disk.

[0049] Specifically, in some embodiments of the present invention, the first transmission disk includes: a first gear disk 311, a transmission gear 312, and a first transmission shaft 313. The first gear disk 311 is disposed on the side of the mounting plate 120 away from the mounting bearing 130; the transmission gear 312 is disposed on the side of the first gear disk 311 away from the mounting plate 120, and the transmission gear 312 is connected to the first gear disk 311, with a second through hole in the middle of the transmission gear 312; the first transmission shaft 313 passes through the through holes on the first gear disk 311, the mounting bearing 130, and the transmission gear 312 simultaneously, so that the first gear disk 311 and the transmission gear 312 move synchronously.

[0050] As can be seen, the first transmission disc is located on the other side of the mounting plate 120, away from the mounting bearing 130. This transmission disc passes through the first through hole and the mounting bearing 130 and is rotatably connected to the mounting plate 120. The first mounting hole is located on the other side of the first transmission disc and is formed along the axial direction of the first transmission disc. Further, the first transmission disc includes a first gear disc 311, a transmission gear 312, and a first transmission shaft 313. The first gear disc 311 is located in the middle of the other side of the mounting plate 120, corresponding to the first through hole. The transmission gear 312 is located on the other side of the first gear disc 311 and is connected to the first gear disc 311 for rotational association. One end of the first transmission shaft 313 passes through the first gear disc 311 and the first through hole and is rotatably connected to the mounting bearing 130, while the other end passes through the second through hole of the transmission gear 312 and is fixedly connected to it. The result of this design is that when the transmission gear 312 rotates, it drives the first gear disc 311 to rotate, thereby causing the first transmission shaft 313 to rotate and output.

[0051] Understandably, the first transmission disc is cleverly positioned on the other side of the mounting plate 120, away from the mounting bearing 130, and rotatably connected to the mounting plate 120 via a first through hole and the mounting bearing 130. This design allows the first transmission disc to rotate stably and reliably on the mounting plate 120. Simultaneously, the first mounting hole on the other side of the first transmission disc, positioned axially, provides a convenient and accurate positioning point for the installation of subsequent components, simplifying the assembly process and improving the assembly efficiency of the transmission system. Furthermore, the design of the components of the first transmission disc—the first gear disc 311, the transmission gear 312, and the first transmission shaft 313—further enhances the performance of the entire output section. The center of the first gear disc 311 corresponds to the first through hole, ensuring a stable position of the first transmission disc on the mounting plate 120. The transmission gear 312 connects to the other side of the first gear disc 311 and is connected to the first transmission shaft 313 via a second through hole in the center, achieving rotational association with the first gear disc 311. This ingenious combination allows the transmission gear 312 to effectively drive the first gear disk 311 to rotate, ultimately driving the first transmission shaft 313 to move. This transmission mechanism not only provides a stable speed multiplication effect, but also maintains a high degree of controllability and precision throughout the entire movement.

[0052] See Figure 2 As shown, in some embodiments of the present invention, the input section includes a second gear disk 210 and a second drive shaft 220. The second gear disk 210 is disposed on the side of the mounting plate 120 away from the mounting bearing 130, and the second gear disk 210 is arranged side by side with the first gear disk 311; one end of the second drive shaft 220 passes through the first through hole and is rotatably connected to the mounting bearing 130, and the other end of the second drive shaft 220 is fixedly connected to the middle part of the second gear disk 210.

[0053] Understandably, by positioning the second gear disk 210 on the side of the mounting plate 120 away from the mounting bearing 130, alongside the first gear disk 311, and directly connected to the mounting plate 120, this layout not only ensures the stability of the input section but also allows for effective collaborative work between the two gears through their adjacent arrangement with the first gear disk 311, resulting in a more coordinated transmission effect. Furthermore, by passing one end of the second drive shaft 220 through the first through hole and rotatably connecting it to the mounting bearing 130, while the other end is fixedly connected to the center of the second gear disk 210, this design enables the second drive shaft 220 to achieve a stable rotatable connection at the mounting bearing 130, while simultaneously ensuring reliable transmission between the shaft and gear by fixing it to the center of the second gear disk 210. This configuration provides a high degree of controllability and stability when transmitting the motion of the input section to the entire transmission system.

[0054] Preferably, a chain 230 is also provided between the second gear disk 210 and the first gear disk 311, and the chain 230 is sleeved on the gear teeth of the second gear disk 210 and the first gear disk 311.

[0055] Specifically, in some embodiments of the present invention, the transmission unit includes: a drive gear 410 and a transmission rod assembly. The drive gear 410 is disposed on the side of the first gear disk 311 away from the mounting plate 120. The drive gear 410 passes through the first mounting hole and is connected to the first gear disk 311. The drive gear 410 is rotatably connected to the transmission gear 312. The drive gear 410 is used to drive the transmission gear 312 to rotate along the moving direction of the drive gear 410. One end of the transmission rod assembly is connected to the drive gear 410, and the other end of the transmission rod assembly is connected to the second gear disk 210. The transmission rod assembly is used to drive the drive gear 410 to move.

[0056] As can be seen, the drive gear 410 is positioned on the other side of the first gear disk 311, away from the mounting plate 120. After passing through the first mounting hole, the drive gear 410 connects to the first gear disk 311 and is rotatably connected to the transmission gear 312. This design allows the drive gear 410 to move circumferentially along the first gear disk 311, enabling the transmission gear 312 to rotate in a specific direction under the rotation of the drive gear 410. This further ensures a multiplier effect in the power transmission process.

[0057] Understandably, one end of the transmission rod assembly is fixedly connected to the drive gear 410, while the other end is connected to the second gear disk 210. This arrangement allows the transmission rod assembly to both fix and connect to the drive gear 410, while simultaneously driving the drive gear 410 to move. This structure enables the drive gear 410 to transmit power precisely and controllably within the transmission system, ensuring the stability and effectiveness of the transmission.

[0058] Specifically, in some embodiments of the present invention, the transmission rod assembly includes: a transmission rod 421 and a fixing member 422; one end of the transmission rod 421 is connected to the drive gear 410, and the other end of the transmission rod 421 is connected to the second gear disk 210, wherein the end of the transmission rod 421 connected to the drive gear 410 is also provided with a sliding hole; the fixing member 422 passes through the sliding hole and is fixedly connected to the drive gear 410, and the fixing member 422 is used to fix the transmission rod 421 and the drive gear 410.

[0059] Specifically, in some embodiments of the present invention, an eccentric shaft is provided at the other end of the transmission rod 421. One end of the eccentric shaft is fixedly connected to the transmission rod 421, and the other end of the eccentric shaft is connected to the second gear disk 210.

[0060] Specifically, in some embodiments of the present invention, the second gear disk 210 is further provided with a second mounting hole, and the other end of the eccentric shaft passes through the second mounting hole and is connected to the second gear disk 210.

[0061] As can be seen, the transmission rod 421 is connected at one end to the drive gear 410 and at the other end to the second gear disk 210. A sliding hole is provided at the end of the transmission rod 421 connected to the drive gear 410, through which the fixing member 422 passes and is fixedly connected to the drive gear 410. When one end of the transmission rod 421 moves circumferentially along the first gear disk 311, the presence of the fixing member 422 allows the drive gear 410 to move along the direction of movement of the other end of the transmission rod 421, thus achieving the transmission effect. An eccentric shaft 423 is also designed at the other end of the transmission rod 421, with one end fixedly connected to the transmission rod 421 and the other end connected to the second gear disk 210. The second gear disk 210 has a second mounting hole, allowing the other end of the eccentric shaft 423 to pass through and connect to the second gear disk 210. Through this design, when one end of the transmission rod 421 moves circumferentially along the first gear disk 311, the presence of the eccentric shaft 423 allows the second gear disk 210 to move synchronously with the transmission rod 421, thereby increasing the rotational speed of the first gear disk 311. Furthermore, through the design of the transmission rod assembly, utilizing the sliding hole, the fixing member 422, and the eccentric shaft 423, effective transmission and control of the drive gear 410 and the second gear disk 210 are achieved. This layout enables the transmission rod assembly to stably transmit power within the transmission system, providing a high degree of controllability and flexibility for the movement of the entire transmission unit.

[0062] It is understandable that by connecting one end of the transmission rod 421 to the drive gear 410 and the other end to the second gear disk 210, an effective connection between the two key components is achieved. Through the sliding hole at the connection end of the transmission rod 421 and the drive gear 410, the fixing member 422 passes through and is fixedly connected to the drive gear 410, so that when one end of the transmission rod 421 moves circumferentially along the first gear disk 311, the fixing member 422 can drive the drive gear 410 to move along the direction of movement of the other end of the transmission rod 421. This mechanism achieves coordinated movement between the transmission rod 421 and the drive gear 410, effectively transmitting power. Secondly, an eccentric shaft 423 is provided at the other end of the transmission rod 421. One end of the eccentric shaft 423 is fixedly connected to the transmission rod 421, and the other end is connected to the second gear disk 210. The second gear disk 210 has a second mounting hole, allowing the other end of the eccentric shaft 423 to pass through and connect to the second gear disk 210. This design, through the setting of the eccentric shaft 423, allows the drive transmission rod 421 to drive the drive gear 410 to rotate when the second gear disk 210 rotates. This concept enables the movement of the first transmission shaft 313 to be precisely controlled by the transmission rod 421, thereby achieving flexible control of the first transmission shaft 313.

[0063] Specifically, in some embodiments of the present invention, the sliding hole is elongated.

[0064] Understandably, the elongated sliding hole design increases the flexibility of the drive rod 421 in connecting to the drive gear 410. Due to its elongated shape, compared to a traditional circular sliding hole, the elongated sliding hole provides greater freedom of movement for the drive rod 421, accommodating a wider range of motion trajectories. This flexibility allows the drive rod 421 to move more smoothly along the elongated sliding hole, thereby enhancing the coordinated movement between the drive rod 421 and the drive gear 410. Secondly, the elongated sliding hole helps reduce friction and wear. Compared to a circular sliding hole, the long axis of the elongated sliding hole provides a larger contact area, dispersing the contact pressure between the drive rod 421 and the fixed component 422. This helps reduce friction generation, lowers frictional losses during sliding, and extends the service life of the transmission system. Furthermore, the elongated sliding hole also helps to smoothly guide the fixed component 422 during sliding, reducing unnecessary vibration and noise, and improving the overall stability of the transmission system.

[0065] The working process of this invention is as follows: When the input unit is started, the second gear disk drives the eccentric shaft 423 to rotate, and at the same time, the eccentric shaft 423 drives the transmission rod 421 to pull the drive gear 410 to move along the circumference of the drive gear 410, thereby driving the first transmission shaft 313 to rotate. This achieves a transmission effect that doubles the rotational speed.

[0066] In summary, this invention provides a speed multiplier transmission system. It features an input and output section mounted on a mounting base, allowing both sections to rotate flexibly and be rotatably connected to the base. A transmission section is positioned on the other side of the mounting base, with one end connected to the input section and the other to the output section. Through the coordinated operation of the input and transmission sections, the output section is smoothly propelled in the input direction. The resulting advantages include improved flexibility and adjustability, enabling the overall transmission system to adapt more efficiently to different operational needs. Simultaneously, reduced friction between mechanical components lowers energy loss and further enhances the overall efficiency of the transmission system. Furthermore, the simplified structural design not only reduces the weight and size of the transmission system but also effectively lowers manufacturing and maintenance costs.

[0067] The technical solution of the present invention has been described above with reference to the preferred embodiments shown in the accompanying drawings. However, it will be readily understood by those skilled in the art that the scope of protection of the present invention is obviously not limited to these specific embodiments. Without departing from the principles of the present invention, those skilled in the art can make equivalent changes or substitutions to the relevant technical features, and the technical solutions after these changes or substitutions will all fall within the scope of protection of the present invention.

[0068] The above description is merely a preferred embodiment of the present invention and is not intended to limit the invention. Various modifications and variations can be made to the present invention by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the scope of protection of the present invention.

Claims

1. A speed multiplication transmission system, characterized in that, include: Mounting base; An input section and an output section are disposed on one side of the mounting base, and the input section and the output section are rotatably connected to the mounting base respectively; A transmission unit is disposed on the side of the input unit away from the mounting base. One end of the transmission unit is connected to the input unit, and the other end of the transmission unit is connected to the output unit. The transmission unit is used to drive the output unit to move synchronously with the input unit. The mounting base includes: a base; A mounting plate is disposed on the upper surface of the base, and the mounting plate is perpendicular to the base. Two first through holes are arranged side by side along the horizontal direction on one side wall of the mounting plate. The mounting bearing is provided in two sets, and the two sets of mounting bearings are respectively located at both ends of the side of the mounting plate where the first through hole is opened. The mounting bearing is provided corresponding to the first through hole and is fixedly connected to the mounting plate. The output section includes: a first transmission disk disposed on the side of the mounting plate away from the mounting bearing, wherein the first transmission disk passes through the first through hole and the mounting bearing and is rotatably connected to the mounting bearing; The first mounting hole is opened on the side of the first transmission disk away from the mounting plate, and the first mounting hole is set along the axial direction of the first transmission disk. The first transmission disc includes: a first gear disc, disposed on the side of the mounting plate away from the mounting bearing; A transmission gear is disposed on the side of the first gear disk away from the mounting plate. The transmission gear is connected to the first gear disk. A second through hole is opened in the middle of the transmission gear. A first transmission shaft passes through the first gear disk, the mounting bearing, and the through hole on the transmission gear, so that the first gear disk and the transmission gear move synchronously. The input section includes: a second gear disk disposed on the side of the mounting plate away from the mounting bearing, and the second gear disk is arranged side by side with the first gear disk; The second drive shaft has one end passing through the first through hole and rotatably connected to the mounting bearing, and the other end of the second drive shaft is fixedly connected to the middle of the second gear disk. The transmission unit includes: a drive gear disposed on the side of the first gear disk away from the mounting plate; the drive gear passes through the first mounting hole and is connected to the first gear disk; the drive gear is rotatably connected to the transmission gear; the drive gear is used to drive the transmission gear to rotate along the direction of movement of the drive gear. A transmission rod assembly, one end of which is connected to the drive gear, and the other end of which is connected to the second gear disk, is used to drive the drive gear to move; The transmission rod assembly includes: a transmission rod, one end of which is connected to the drive gear, and the other end of which is connected to the second gear disk, wherein the end of the transmission rod connected to the drive gear is also provided with a sliding hole; A fixing member passes through the sliding hole and is fixedly connected to the drive gear. The fixing member is used to fix the transmission rod and the drive gear. An eccentric shaft is also provided at the other end of the transmission rod. One end of the eccentric shaft is fixedly connected to the transmission rod, and the other end of the eccentric shaft is connected to the second gear disk.

2. The speed multiplication transmission system as described in claim 1, characterized in that, The sliding hole is elongated.

3. The speed multiplication transmission system as described in claim 2, characterized in that, The second gear disk is also provided with a second mounting hole, and the other end of the eccentric shaft passes through the second mounting hole and is connected to the second gear disk.