Intelligent resistance bird trainer
By using a motor as a resistance source in the bird training device, the noise problem during training is solved, and intelligent control of noise reduction and resistance adjustment is achieved, improving the user experience and the intelligence of the trainer.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- NANTONG IRONMASTER SPROTING IND
- Filing Date
- 2025-06-18
- Publication Date
- 2026-06-05
AI Technical Summary
Existing bird training devices generate noise during training due to the collision of selection plates, which affects the user experience.
Using a motor as the resistance source, the pulley mechanism is driven by pulling the handle, and the motor provides resistance, reducing noise and realizing intelligent control of resistance adjustment.
It reduces training noise, improves the intelligence of the trainer and the convenience of resistance adjustment, and meets the training needs of different users.
Smart Images

Figure CN224320969U_ABST
Abstract
Description
Technical Field
[0001] This utility model generally relates to the field of fitness equipment, and more particularly to an intelligent resistance flyer trainer. Background Technology
[0002] As people's living standards improve, more and more people are starting to exercise, and fitness equipment is becoming increasingly popular. The fly trainer, a type of multi-functional training device, is favored by fitness enthusiasts for its ease of use, practicality, effectiveness, versatility, and adaptability.
[0003] Existing fly training devices typically use selection plates as the resistance source. Pulling a rope raises the selection plates, thus achieving muscle training. During training, the selection plates collide, generating noise. Utility Model Content
[0004] In view of the above-mentioned defects or deficiencies in the prior art, it is desirable to provide a smart resistive bird trainer and device that reduces noise.
[0005] In a first aspect, the intelligent resistive bird trainer of this utility model is characterized by comprising multiple resistive bird training units, wherein any two adjacent resistive bird training units are connected by a connecting pipe.
[0006] The resistive bird training unit includes:
[0007] A frame, wherein a plurality of first pulleys are rotatably connected to the frame;
[0008] A resistance mechanism includes a first pull rope, a motor, a speed reduction device, and a drum. The speed reduction device is connected to the motor and has an output end. The drum is driven to the output end. The first pull rope is wound around the drum and has a first end and a second end. The first end is fixed to the drum.
[0009] A first pulley mechanism includes a second pulley and a first pulley seat, wherein the second pulley is rotatably connected to the first pulley seat, and the first pulley seat is connected to a second end; and
[0010] A pull rope mechanism includes a second pull rope and a handle. The second pull rope passes over a second pulley and has a third end and a fourth end, the third end being connected to the handle.
[0011] Pulling the handle causes the first pulley mechanism to move away from the drum via the second pull rope, thereby shortening the length of the first pull rope wound on the drum.
[0012] According to the technical solution provided in the embodiments of this application, by pulling the handle, the third end is pulled out, causing the first pulley mechanism to move away from the resistance mechanism. The first pulley mechanism pulls out the first pull rope, causing the drum to rotate. The motor provides resistance for the rotation of the drum, which in turn provides resistance for pulling the handle. Compared to using a selector plate as a resistance source, using a motor to provide resistance results in less noise and is easier to adjust. Attached Figure Description
[0013] Other features, objects, and advantages of this application will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:
[0014] Figure 1 This is a schematic diagram of the structure of the resistive bird training unit of the intelligent resistive bird trainer of this utility model;
[0015] Figure 2 for Figure 1 A magnified view of a section at point A in the middle;
[0016] Figure 3 for Figure 1 A magnified view of a section at point B in the middle;
[0017] Figure 4 This is a schematic diagram of the structure of the resistive bird training unit of the intelligent resistive bird trainer of this utility model;
[0018] Figure 5 This is a schematic diagram of the structure of the resistive bird training device of this utility model. Detailed Implementation
[0019] The present application will now be described in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the relevant utility model and not intended to limit the scope of the utility model. Furthermore, it should be noted that, for ease of description, only the parts relevant to the utility model are shown in the accompanying drawings.
[0020] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. This application will now be described in detail with reference to the accompanying drawings and embodiments.
[0021] Please refer to Figures 1-5A resistance bird training device includes multiple resistance bird training units 10, with any two adjacent resistance bird training units 10 connected by a connecting pipe 20. Each resistance bird training unit 10 includes: a frame 100, with multiple first pulleys 110 rotatably connected to the frame 100; a resistance mechanism 200, which includes a first pull rope, a motor 210, a reduction gear, and a drum. The reduction gear is connected to the motor 210 and has an output end, and the drum is drivenly connected to the output end. The first pull rope is wound around the drum and has a first end and a second end, with the first end fixed to the drum. The pulley mechanism 300 includes a second pulley 310 and a first pulley seat 320, the second pulley 310 and the first pulley seat 320 being rotatably connected, and the first pulley seat 320 being connected to a second end; and the rope pulling mechanism 400 includes a second rope 410 and a handle 420, the second rope 410 passing around the second pulley 310, the second rope 410 having a third end and a fourth end 412, the third end being connected to the handle 420, pulling the handle 420, and driving the first pulley mechanism 300 away from the drum through the second rope 410, so that the length of the first rope wound on the drum is shortened.
[0022] In this embodiment of the invention, the resistive flyer training device is equipped with multiple resistive flyer training units 10, allowing a single user to perform bilateral training or multiple users to train simultaneously. Any two adjacent resistive flyer training units 10 are connected by a connecting pipe 20, ensuring the stability of the resistive flyer training device. The resistive flyer training device can also be equipped with one or more of the following combinations: a display screen, a shelf, and hooks, to further expand its functionality. The display screen can display training-related data in real time, and users can also control the screen to adjust the resistance, further enhancing the intelligence of the trainer.
[0023] The second pull rope 410 passes around the first pulley 110, which can reduce the resistance during the movement of the second pull rope 410. The frame 100 is rotatably connected with multiple first pulleys 110. The first pulleys 110 can be set at the position where the direction of the second pull rope 410 needs to be changed, which facilitates the routing of the second pull rope 410.
[0024] The resistance mechanism 200 includes a motor 210, a reduction gear, and a drum. The motor 210 is fixed to the frame 100. The motor 210 drives the drum to rotate through the reduction gear, which reduces the rotational speed of the drum. The motor 210 provides the power source for the drum's rotation. The first pull rope has a first end and a second end. The first end is fixed to the drum, allowing the drum to rotate and the first pull rope to wind around it. The first end can be fixed to the drum by methods such as knotting, adhesive, or binding. The second end is connected to a first pulley seat 320. When the first pulley mechanism 300 moves away from the resistance mechanism 200, it drives the drum to rotate through the first pull rope, while the motor provides a reverse driving force to the drum. When the tension of the first pull rope on the drum is greater than the reverse driving force provided by the motor, the first pulley mechanism 300 will move away from the resistance mechanism 200, and the length of the first pull rope wound around the drum will shorten. When the tension of the first pull rope on the drum is less than the reverse driving force provided by the motor to the drum, the first pulley mechanism 300 will move closer to the resistance mechanism 200, and the length of the first pull rope wound on the drum will increase. By changing the magnitude of the reverse driving force provided by the motor to the drum, the force on the first pull rope when the first pulley mechanism 300 moves away from the resistance mechanism 200 can be adjusted, that is, the resistance of the first pulley mechanism 300 moving away from the resistance mechanism 200 can be adjusted.
[0025] The rope-pulling mechanism 400 includes a second rope 410 and a handle 420. The second rope 410 passes around a second pulley 310. By pulling the handle 420, the third end is pulled out, causing the first pulley mechanism 300 to move away from the resistance mechanism 200. The first pulley mechanism 300 then pulls out the first rope, causing the drum to rotate. The motor provides resistance to the drum's rotation, which in turn provides resistance to pulling the handle 420. Compared to using a selector plate as a resistance source, using a motor to provide resistance results in less noise and is easier to adjust. The motor can be precisely controlled by electrical signals or programs to output torque, thereby achieving quantitative adjustment and intelligent control of the resistance, meeting the training needs of different users.
[0026] Furthermore, multiple parallel guide ropes 120 are fixedly connected to the frame 100. The first pulley mechanism 300 includes a guide plate 330, which is fixedly connected to the first pulley seat 320. Multiple guide holes are spaced apart on the guide plate 330, and a guide rope 120 passes through one guide hole.
[0027] In this embodiment of the invention, as the first pulley mechanism 300 moves closer to or further away from the resistance mechanism 200, the guide plate 330 moves relative to the guide rope 120. The cooperation between the guide rope 120 and the guide plate 330 prevents the first pulley mechanism 300 from twisting, thus improving the reliability of the resistance bird training unit 10.
[0028] Furthermore, the frame 100 is provided with two guide ropes 120, the guide plate 330 is provided with two guide holes, and the second pulley 310 is located between the two guide ropes 120.
[0029] In this embodiment of the invention, as the first pulley mechanism 300 moves closer to or further away from the resistance mechanism 200, the guide plate 330 moves relative to the guide rope 120. The cooperation between the guide rope 120 and the guide plate 330 prevents the first pulley mechanism 300 from twisting, thus improving the reliability of the resistance bird training unit 10.
[0030] Furthermore, a guide sleeve 331 is detachably and fixedly connected to the guide hole, and the guide sleeve 331 is fitted onto the guide rope 120.
[0031] In embodiments of this invention, the guide sleeve 331 can be made of a wear-resistant material with low friction. By providing the guide sleeve 331, wear on the guide rope 120 can be reduced, improving the reliability of the resistance bird training unit 10.
[0032] Furthermore, a buffer block 130 is fixedly connected to the frame 100. The buffer block 130 is located between the resistance mechanism 200 and the first pulley mechanism 300, and the buffer block 130 is located on the movement path of the first pulley mechanism 300.
[0033] In the embodiments of this utility model, the buffer block 130 can stop the first pulley mechanism 300, and the buffer block 130 can buffer the impact of the first pulley mechanism 300, reduce noise, and avoid unnecessary collisions.
[0034] Furthermore, the frame 100 is fixedly connected to a guide rod 140, and the guide rod 140 is slidably connected to an adjusting seat 150. The adjusting seat 150 is provided with an extendable and retractable positioning rod. The frame 100 is provided with multiple positioning holes 160 on the movement path of the adjusting seat 150. The adjusting seat 150 is connected to a second pulley mechanism 500. The third end passes through the second pulley mechanism 500 and is connected to the pull handle 420. The fourth end 412 is fixed to the adjusting seat 150. The second pull rope is provided with a first tension section 413 near the third end and a second tension section 414 near the fourth end 412. The first tension section 413 and the second tension section 414 are located on both sides of the adjusting seat 150. The positioning rod is inserted into any positioning hole 160 to prevent the adjusting seat 150 from sliding relative to the guide rod 140.
[0035] In an embodiment of this utility model, the adjusting seat 150 is connected to a second pulley mechanism 500, and the third end passes through the second pulley mechanism 500 and is connected to the handle 420. By placing the positioning rod into different positioning holes 160, the relative position of the adjusting seat 150 and the guide rod 140 can be changed, that is, the initial position of the handle 420 can be changed, so as to meet the different training needs of the user.
[0036] by Figure 1 The following is a detailed explanation of the orientation shown. When adjusting the position of the adjusting seat 150, the positioning rod is pulled out of the positioning hole 160. At this time, the adjusting seat 150 can slide on the guide rod 140. When the adjusting seat 150 is slid upward, it pulls the second tension section 414 upward, and the second pull rope 410 drives the first tension section 413 upward. When the adjusting seat 150 is slid downward, it pulls the first tension section 413 downward, and the second pull rope 410 drives the second tension section 414 downward. Regardless of the position of the adjusting seat 150, the second pull rope 410 can follow the movement of the adjusting seat 150, and the second pull rope 410 always remains taut.
[0037] Furthermore, the second pulley mechanism 500 includes a second pulley seat 510 and at least one third pulley 520, the third pulley 520 being rotatably connected to the second pulley seat 510, and the second pulley seat 510 being rotatably connected to the adjusting seat 150.
[0038] In this embodiment of the invention, when the user grips the handle 420 and pulls out the second pull rope 410, it will cause the third pulley 520 to rotate relative to the second pulley seat 510, and also cause the second pulley seat 510 to rotate relative to the adjusting seat 150, so that the second pull rope 410 can be pulled out more smoothly. It is possible, but not limited to, that two third pulleys 520 are rotatably connected to the second pulley seat 510, and the second pull rope 410 passes between the two third pulleys 520.
[0039] Furthermore, a stop 430 is fixedly connected to the third end, which is used to prevent the third end from passing through the second pulley mechanism 500.
[0040] In this embodiment of the utility model, the stop 430 cannot pass through the second pulley mechanism 500, thus preventing the handle 420 from passing through the second pulley mechanism 500 and ensuring that the second pull rope 410 is in a taut state.
[0041] Furthermore, multiple handles 21 are provided on the connecting pipe 20 located at the top of the frame 100.
[0042] In this embodiment of the invention, the user can perform upward training by gripping the handle 21, thus expanding the function of the resistance flying bird training device.
[0043] The above description is merely a preferred embodiment of this application and an explanation of the technical principles employed. Those skilled in the art should understand that the scope of the utility model involved in this application is not limited to the technical solutions formed by specific combinations of the above-described technical features, but should also cover other technical solutions formed by arbitrary combinations of the above-described technical features or their equivalents without departing from the inventive concept. For example, technical solutions formed by substituting the above features with (but not limited to) technical features with similar functions disclosed in this application.
Claims
1. A smart resistive bird-flying trainer, characterized in that, It includes multiple resistive bird training units, and any two adjacent resistive bird training units are connected by a connecting tube. The resistive bird training unit includes: A frame, wherein a plurality of first pulleys are rotatably connected to the frame; A resistance mechanism includes a first pull rope, a motor, a speed reduction device, and a drum. The speed reduction device is connected to the motor and has an output end. The drum is driven to the output end. The first pull rope is wound around the drum and has a first end and a second end. The first end is fixed to the drum. A first pulley mechanism includes a second pulley and a first pulley seat, wherein the second pulley is rotatably connected to the first pulley seat, and the first pulley seat is connected to a second end; and A pull rope mechanism includes a second pull rope and a handle. The second pull rope passes over a second pulley and has a third end and a fourth end, the third end being connected to the handle. Pulling the handle causes the first pulley mechanism to move away from the drum via the second pull rope, thereby shortening the length of the first pull rope wound on the drum.
2. The intelligent resistive bird trainer according to claim 1, characterized in that, Multiple parallel guide ropes are fixedly connected to the frame. The first pulley mechanism includes a guide plate, which is fixedly connected to the first pulley seat. Multiple guide holes are spaced apart on the guide plate, and one guide rope passes through one of the guide holes.
3. The intelligent resistive bird trainer according to claim 2, characterized in that, The frame is provided with two guide ropes, the guide plate is provided with two guide holes, and the second pulley is located between the two guide ropes.
4. The intelligent resistive bird trainer according to claim 2, characterized in that, The guide hole is detachably and fixedly connected to a guide sleeve, which is fitted onto the guide rope.
5. The intelligent resistive bird trainer according to claim 2, characterized in that, A buffer block is fixedly connected to the frame. The buffer block is located between the resistance mechanism and the first pulley mechanism, and is located on the movement path of the first pulley mechanism.
6. The intelligent resistive bird trainer according to claim 1, characterized in that, The frame is fixedly connected to a guide rod, and the guide rod is slidably connected to an adjusting seat. The adjusting seat is provided with an extendable and retractable positioning rod. The frame is provided with multiple positioning holes along the movement path of the adjusting seat. The adjusting seat is connected to a second pulley mechanism. The third end passes through the second pulley mechanism and is connected to the handle. The fourth end is fixed to the adjusting seat. The second pull rope has a first tension section near the third end and a second tension section near the fourth end. The first tension section and the second tension section are located on both sides of the adjusting seat. The positioning rod is inserted into any of the positioning holes to prevent the adjusting seat from sliding relative to the guide rod.
7. The intelligent resistive bird trainer according to claim 6, characterized in that, The second pulley mechanism includes a second pulley seat and at least one third pulley, wherein the third pulley is rotatably connected to the second pulley seat, and the second pulley seat is rotatably connected to the adjusting seat.
8. The intelligent resistive bird trainer according to claim 6, characterized in that, The third end is fixedly connected to a stop member, which is used to prevent the third end from passing through the second pulley mechanism.
9. The intelligent resistive bird trainer according to claim 1, characterized in that, Multiple handles are provided on the connecting pipe located at the top of the frame.