A high-vibration magnetic motor with a low-noise structure

By employing bracket limiting, honeycomb design, and sound-absorbing cotton rings in the high-vibration magnet motor to absorb noise, and combining heat conduction plates and heat dissipation fins to manage heat, the noise pollution problem of traditional high-vibration magnet motors is solved, achieving low noise and efficient heat dissipation.

CN224438688UActive Publication Date: 2026-06-30NINGBO XINTAI TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NINGBO XINTAI TECH CO LTD
Filing Date
2025-07-01
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Traditional high-vibration magnet motors often use a single material and a simple thin-walled structure for their housings, which makes it easy for the vibration noise generated by the internal parts of the motor to be transmitted to the outside, causing noise pollution.

Method used

Design a high-vibration magnetic motor with a low-noise structure. It adopts bracket limiting components, combined with honeycomb design and sound-absorbing cotton rings for initial and secondary noise absorption, and uses heat conduction plates and heat dissipation fins for heat management. The detachable limiting mechanism improves the convenience of maintenance.

Benefits of technology

It effectively reduces the transmission and generation of vibration noise, improves sound insulation performance, ensures heat dissipation of components and prevents noise caused by overheating, and enhances the convenience of maintenance.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224438688U_ABST
Patent Text Reader

Abstract

This utility model relates to a high-vibration magnetic motor with a low-noise structure, including a high-vibration magnetic motor body. A set of auxiliary mechanisms are symmetrically arranged on the surface of the high-vibration magnetic motor body. This utility model uses a bracket to accommodate and limit the magnet, coil, rotor, stator and other components. Then, the bracket is limited to the inside of the shell by the cooperation between the guide rod and the guide bracket. When the limiting ring and the protrusion are disassembled, the components can be moved out with the bracket, improving the convenience of maintenance. The honeycomb design of the bracket side wall can initially absorb and block the vibration noise generated by the components during operation. The sound-absorbing cotton ring absorbs the vibration noise a second time, improving the sound insulation performance. Several heat-conducting plates can quickly conduct the heat generated by the components during operation, and the heat dissipation fins can quickly dissipate the heat inside the shell to the surrounding environment, avoiding the expansion or deformation of the components due to overheating, thereby reducing the noise generated by the friction or collision of the components.
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Description

Technical Field

[0001] This utility model relates to the field of high-vibration magnetic motor technology, and in particular to a high-vibration magnetic motor with a low-noise structure. Background Technology

[0002] A high-vibration magnet motor typically refers to a motor that uses the interaction between a strong magnet and an electric current to generate a powerful vibration effect.

[0003] Traditional high-vibration magnet motors often use a single material and a simple thin-walled structure for their housings. As a result, the vibration noise generated by the internal parts of the motor is easily transmitted to the outside, causing noise pollution. In view of this, we propose a high-vibration magnet motor with a low-noise structure. Utility Model Content

[0004] The purpose of this utility model is to overcome the shortcomings of the existing technology, adapt to the needs of reality, and provide a high-vibration magnetic motor with a low-noise structure. This solves the technical problem that the housing of current traditional high-vibration magnetic motors is mostly made of a single material and has a simple thin-walled structure, so the vibration noise generated by the operation of the internal parts of the motor is easily transmitted to the outside, causing noise pollution.

[0005] To achieve the purpose of this utility model, the technical solution adopted by this utility model is as follows: design a high-vibration magnetic motor with a low-noise structure, including a high-vibration magnetic motor body, and a set of auxiliary mechanisms symmetrically arranged on the surface of the high-vibration magnetic motor body;

[0006] The main body of the high-vibration magnetic motor includes a mounting plate. A limiting ring is fixed on the surface of the mounting plate. A protrusion is matched and engaged inside the limiting ring. A shell is fixed at the rear end of the protrusion. A set of guide brackets is symmetrically fixed inside the shell. A set of guide rods is symmetrically engaged inside the set of guide brackets. A bracket is fixed between the set of guide rods. Sound-absorbing cotton rings are embedded in the shell interlayer. Several heat-conducting plates are evenly embedded on the inner sides of the upper and lower ends of the shell. Heat dissipation fins are connected to the outer ends of the heat-conducting plates.

[0007] Preferably, the protrusion and the outer shell are integrally formed, and the bracket and the outer shell form a locking structure through the guide rod and the guide bracket.

[0008] Preferably, the sidewalls of the support are honeycomb-shaped, and both the upper and lower surfaces of the support are open openings.

[0009] Preferably, the heat-conducting plate is made of copper, the heat dissipation fins are made of aluminum, and the heat-conducting plate and the heat dissipation fins are connected by welding.

[0010] Preferably, the auxiliary mechanism includes a cylindrical frame, a set of cylindrical frames symmetrically fixed on one side of a limiting ring frame, a U-shaped locking rod penetrating inside the set of cylindrical frames, a set of limiting ring plates symmetrically fixed on the outer surface of the U-shaped locking rod, and a spring connected to one side of the limiting ring plate.

[0011] Preferably, the limiting ring frame is connected to the cylinder frame, the end of the U-shaped clamp passes through the side of the limiting ring frame, and the surface of the protrusion frame is provided with a groove that matches the end of the U-shaped clamp.

[0012] Preferably, the U-shaped lever is formed into an elastic structure by a limiting ring plate, a spring, and a cylindrical frame, with the outer wall of the limiting ring plate fitting against the inner wall of the cylindrical frame.

[0013] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0014] 1. This utility model uses a bracket to accommodate and limit the magnet, coil, rotor, stator, and other components. Then, the bracket is confined to the inside of the outer shell by the cooperation between the guide rod and the guide bracket. When disassembling the limiting ring and the protrusion, the components can be moved out with the bracket, improving the convenience of maintenance. The honeycomb design of the bracket side wall can effectively absorb and block the vibration noise generated by the components during operation. The sound-absorbing cotton ring absorbs the vibration noise a second time, improving the sound insulation performance. Several heat-conducting plates can quickly conduct the heat generated by the components during operation, and the heat dissipation fins can quickly dissipate the heat inside the outer shell to the surrounding environment, avoiding the expansion or deformation of the components due to overheating, thereby reducing the noise generated by the friction or collision of the components.

[0015] 2. In this utility model, pulling the U-shaped lever outward causes the end of the U-shaped lever to disengage from the groove on the surface of the protrusion. At this time, the protrusion is unrestricted and can be moved outward directly to separate from the limiting ring frame, which facilitates the subsequent removal of the bracket and its internal components for maintenance. During reassembly, the protrusion is locked into the limiting ring frame by pulling the U-shaped lever outward. Then, the U-shaped lever is released, and the end of the U-shaped lever pops out and effectively engages in the groove on the surface of the protrusion due to the spring rebound force, thereby achieving rapid positioning of the protrusion and the outer shell. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the overall structure of this utility model from another perspective;

[0018] Figure 3 This is a schematic diagram of the separation structure of the limiting ring frame and the protrusion frame of this utility model;

[0019] Figure 4 This is a partial cross-sectional structural diagram of the auxiliary mechanism of this utility model;

[0020] Figure 5 This is a partial disassembly diagram of the main body of the high-vibration magnetic motor of this utility model.

[0021] Figure 6 This is a partial cross-sectional structural diagram of the main body of the high-vibration magnet motor of this utility model;

[0022] In the diagram: 1. Main body of the high-vibration magnet motor; 2. Auxiliary mechanism;

[0023] 101. Mounting plate; 102. Limiting ring frame; 103. Plug; 104. Outer shell; 105. Guide bracket; 106. Guide rod; 107. Bracket; 108. Sound-absorbing cotton ring; 109. Heat-conducting plate; 110. Heat dissipation fins;

[0024] 201. Cylindrical frame; 202. U-shaped locking rod; 203. Limiting ring plate; 204. Spring. Detailed Implementation

[0025] The present invention will be further described below with reference to the accompanying drawings and embodiments:

[0026] A high-vibration magnetic motor with a low-noise structure, see [link / reference]. Figures 1 to 6 It includes a strong vibration magnet motor body 1, and a set of auxiliary mechanisms 2 are symmetrically arranged on the surface of the strong vibration magnet motor body 1;

[0027] The main body 1 of the high-vibration magnet motor includes a mounting plate 101. A limiting ring frame 102 is fixedly provided on the surface of the mounting plate 101. A protrusion 103 is matched and engaged inside the limiting ring frame 102. A housing 104 is fixedly provided at the rear end of the protrusion 103. A set of guide brackets 105 are symmetrically fixed inside the housing 104. A set of guide rods 106 are symmetrically engaged inside the set of guide brackets 105. A bracket 107 is fixed between the set of guide rods 106. The protrusion 103 and the housing 104 are integrally formed. The bracket 107 is connected to the guide rods 106 and the guide rods 106. The card holder 105 and the outer shell 104 form a snap-fit ​​structure. Furthermore, the side wall of the bracket 107 is honeycomb-shaped, and the upper and lower surfaces of the bracket 107 are open. Sound-absorbing cotton rings 108 are embedded in the interlayer of the outer shell 104. Several heat-conducting plates 109 are evenly embedded on the inner side of the upper and lower ends of the outer shell 104. Heat dissipation fins 110 are connected to the outer ends of the heat-conducting plates 109. Furthermore, the heat-conducting plates 109 are made of copper, and the heat dissipation fins 110 are made of aluminum. The heat-conducting plates 109 and the heat dissipation fins 110 are welded together. This invention uses a bracket 107 to accommodate and limit the magnet, coil, rotor, stator, and other components. Then, the bracket 107 is confined inside the outer shell 104 by the cooperation between the guide rod 106 and the guide bracket 105. When the limiting ring 102 and the protrusion 103 are subsequently disassembled, the components can be moved out with the bracket 107, improving the convenience of maintenance. The honeycomb design of the side wall of the bracket 107 can effectively absorb and block the vibration noise generated by the components during operation. The sound-absorbing cotton ring 108 absorbs the vibration noise a second time, improving the sound insulation performance. Several heat-conducting plates 109 can quickly conduct the heat generated by the components during operation, and the heat dissipation fins 110 can quickly dissipate the heat inside the outer shell 104 to the surrounding environment, avoiding the expansion or deformation of the components due to overheating, thereby reducing the noise generated by the friction or collision of the components.

[0028] It is worth noting that the auxiliary mechanism 2 includes a cylindrical frame 201. A set of cylindrical frames 201 are symmetrically fixed on one side of the limiting ring frame 102. A U-shaped locking rod 202 passes through the inside of the set of cylindrical frames 201. The limiting ring frame 102 is connected to the cylindrical frame 201. The end of the U-shaped locking rod 202 passes through the side of the limiting ring frame 102. The surface of the protrusion 103 is provided with a locking groove that matches the end of the U-shaped locking rod 202. A set of limiting ring plates 203 are symmetrically fixed on the outer surface of the U-shaped locking rod 202. A spring 204 is connected to one side of the limiting ring plate 203. Furthermore, the U-shaped locking rod 202 forms an elastic structure with the cylindrical frame 201 through the limiting ring plate 203 and the spring 204. The outer wall of the limiting ring plate 203 is in contact with the inner wall of the cylindrical frame 201. In this invention, pulling the U-shaped lever 202 outward causes the end of the U-shaped lever 202 to disengage from the groove on the surface of the protrusion 103. At this time, the protrusion 103 is unrestricted and can move directly outward to separate from the limiting ring frame 102, which facilitates the subsequent removal of the bracket 107 and its internal components for maintenance. During reassembly, the protrusion 103 is locked into the limiting ring frame 102 while the U-shaped lever 202 is pulled outward. Then, the U-shaped lever 202 is released, and the end of the U-shaped lever 202 pops out and effectively engages in the groove on the surface of the protrusion 103, thereby achieving rapid positioning of the protrusion 103 and the outer shell 104.

[0029] Working principle: The bracket 107 accommodates and limits the magnet, coil, rotor, stator, and other components. Then, the guide rod 106 and guide bracket 105 work together to confine the bracket 107 inside the housing 104. When disassembling the limiting ring bracket 102 and the protrusion 103, pulling the U-shaped lever 202 outwards causes its end to disengage from the groove on the surface of the protrusion 103. At this point, the protrusion 103 is unrestricted and can move directly outwards, separating from the limiting ring bracket 102. Simultaneously, the components can be moved out with the bracket 107, improving maintenance convenience. After maintenance, by pulling the U-shaped lever 202 outwards, the protrusion 103 is locked inside the limiting ring bracket 102, and then released. The U-shaped lever 202, under the influence of the spring 204's rebound force, pops out at its end and engages in the slot on the surface of the protrusion 103, achieving rapid positioning of the protrusion 103 and the outer shell 104. The honeycomb design of the side wall of the bracket 107 can initially absorb and block the vibration noise generated during the operation of the components. The sound-absorbing cotton ring 108 further absorbs the vibration noise, improving the sound insulation performance. Several heat-conducting plates 109 can quickly conduct the heat generated during the operation of the components, and the heat dissipation fins 110 can quickly dissipate the heat inside the outer shell 104 to the surrounding environment, avoiding the expansion or deformation of the components due to overheating, thereby reducing the noise generated by the friction or collision of the components.

[0030] The embodiments disclosed herein are preferred embodiments, but are not limited thereto. Those skilled in the art can readily grasp the spirit of this utility model based on the above embodiments and make different extensions and variations. However, as long as they do not depart from the spirit of this utility model, they are all within the protection scope of this utility model.

Claims

1. A high-vibration magnetic motor with a low-noise structure, characterized in that, It includes a strong vibration magnet motor body (1), and a set of auxiliary mechanisms (2) are symmetrically arranged on the surface of the strong vibration magnet motor body (1). The main body (1) of the high-vibration magnet motor includes a mounting plate (101). A limiting ring frame (102) is fixed on the surface of the mounting plate (101). A protrusion frame (103) is matched and engaged inside the limiting ring frame (102). A shell (104) is fixed at the rear end of the protrusion frame (103). A set of guide brackets (105) is symmetrically fixed inside the shell (104). A set of guide rods (106) is symmetrically engaged inside the set of guide brackets (105). A bracket (107) is fixed between the set of guide rods (106). A sound-absorbing cotton ring (108) is embedded in the interlayer of the shell (104). Several heat-conducting plates (109) are evenly embedded on the inner side of the upper and lower ends of the shell (104). A heat dissipation fin (110) is connected to the outer end of the heat-conducting plate (109).

2. A high-vibration magnetic motor with a low-noise structure as described in claim 1, characterized in that, The protrusion (103) and the outer shell (104) are integrally formed, and the bracket (107) forms a locking structure with the outer shell (104) through the guide rod (106) and the guide bracket (105).

3. A high-vibration magnetic motor with a low-noise structure as described in claim 1, characterized in that, The sidewall of the bracket (107) is honeycomb-shaped, and both the upper and lower surfaces of the bracket (107) are open openings.

4. A high-vibration magnetic motor with a low-noise structure as described in claim 1, characterized in that, The heat-conducting plate (109) is made of copper, and the heat dissipation fins (110) are made of aluminum. The heat-conducting plate (109) and the heat dissipation fins (110) are connected by welding.

5. A high-vibration magnetic motor with a low-noise structure as described in claim 1, characterized in that, The auxiliary mechanism (2) includes a cylindrical frame (201). A set of cylindrical frames (201) are symmetrically fixed on one side of the limiting ring frame (102). A U-shaped locking rod (202) runs through the inside of the set of cylindrical frames (201). A set of limiting ring plates (203) are symmetrically fixed on the outer surface of the U-shaped locking rod (202). A spring (204) is connected to one side of the limiting ring plate (203).

6. A high-vibration magnetic motor with a low-noise structure as described in claim 5, characterized in that, The limiting ring frame (102) is connected to the cylinder frame (201), the end of the U-shaped clamp (202) passes through the side of the limiting ring frame (102), and the surface of the protrusion frame (103) is provided with a groove that matches the end of the U-shaped clamp (202).

7. A high-vibration magnetic motor with a low-noise structure as described in claim 5, characterized in that, The U-shaped lever (202) forms an elastic structure with the limit ring plate (203), spring (204) and cylinder frame (201), and the outer wall of the limit ring plate (203) is in contact with the inner wall of the cylinder frame (201).