Pet teasing structure and recharging seat

By using a conductive sleeve and brush structure, the problem of unstable power supply in laser pet toys is solved, achieving a stable power supply, improving the reliability and service life of the equipment, and enhancing safety and user experience.

CN224368716UActive Publication Date: 2026-06-19UNION OPTECH +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
UNION OPTECH
Filing Date
2025-06-24
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In existing laser-powered pet toys, the unstable power supply to the laser generator leads to poor contact, affecting normal use.

Method used

It adopts a conductive sleeve and brush structure. The conductive sleeve is sleeved on the output end of the drive component, and the brush can rotate and abut against the conductive sleeve. The laser generator is electrically connected to the conductive sleeve to provide a stable power supply.

Benefits of technology

It improves power supply stability, extends equipment lifespan, reduces maintenance costs, enhances safety and user experience, and ensures the normal operation of pet toys.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224368716U_ABST
    Figure CN224368716U_ABST
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Abstract

The utility model discloses a kind of teasing structure and back charging seat, it is related to intelligent teasing technology field, and wherein, teasing structure includes driving part, conducting assembly and laser generator, the conducting assembly includes conducting sleeve and electric brush, the conducting sleeve is sleeved in the output end of the driving part, the electric brush is located in the driving part, the electric brush with The conducting sleeve rotatable abuts, to make the electric brush with The conducting sleeve electric connection;The laser generator is connected with the output end of the driving part, the laser generator with The conducting sleeve electric connection;The utility model aims at improving the stability of teasing structure power supply.
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Description

Technical Field

[0001] This utility model relates to the field of intelligent pet-playing technology, and in particular to a pet-playing structure and a rechargeable base. Background Technology

[0002] As living standards improve, pets are gaining importance in people's lives, and more and more people are choosing to keep pets for companionship. To meet the entertainment needs of pets, the pet toy market is booming, among which laser pet toys are popular with pet owners due to their unique interactivity and fun.

[0003] Existing laser pet-playing structures typically include a housing, a driver, a laser generator, and a reflector. The housing houses the driver, laser generator, and reflector, and has a through-hole for the laser to pass through. The driver moves the laser generator, which emits laser light towards the reflector. After being reflected by the reflector, the laser light passes through the through-hole and moves across the ground or other surfaces, attracting pets to chase it and achieving the pet-playing effect. During use, the laser generator requires a stable power supply. In related technologies, the driver is typically connected to a turntable, with the driver and laser generator located on opposite sides of the turntable. The turntable has a ring-shaped printed circuit layer. A probe is fixed to the driver and rotatably contacts the ring-shaped printed circuit layer, establishing an electrical connection between the probe and the turntable. The laser generator is also electrically connected to the turntable, and the power supply is connected to the probe. When the driver rotates the turntable, the probe becomes conductive with the ring-shaped printed circuit layer, providing continuous power to the laser generator.

[0004] However, since the ring-shaped printed circuit layer is made of metal, after repeated use, the friction between the stylus and the ring-shaped printed circuit layer can easily cause the metal layer to wear down, resulting in poor contact, unstable power supply to the laser generator, and affecting the normal use of the pet toy. Utility Model Content

[0005] The main purpose of this invention is to propose a pet-playing structure and a recharge socket, which aims to improve the stability of the power supply of the pet-playing structure.

[0006] To achieve the above objectives, the pet-playing structure proposed in this utility model includes:

[0007] Drive components;

[0008] A conductive assembly, comprising a conductive sleeve and a brush, wherein the conductive sleeve is fitted onto the output end of the driving member, and the brush is disposed on the driving member, the brush being rotatably abutting against the conductive sleeve to electrically connect the brush to the conductive sleeve; and

[0009] A laser generator is connected to the output end of the drive unit and electrically connected to the conductive sleeve.

[0010] In one embodiment, the brush includes a connecting portion and at least one fork arm, the connecting portion being connected to the drive member and the fork arm respectively, and the fork arm being rotatably abutting against the outer peripheral wall of the conductive sleeve.

[0011] In one embodiment, the brush includes two forked arms, and the two ends of the connecting portion are respectively connected to the two forked arms. The two forked arms are rotatably abutted against the outer peripheral wall of the conductive sleeve, and the conductive sleeve is located between the two forked arms.

[0012] In one embodiment, each of the forks includes two spaced-apart support arms, each support arm having a contact portion adapted to the outer peripheral wall of the conductive sleeve.

[0013] In one embodiment, the conductive component includes two brushes, the outer peripheral wall of the conductive sleeve is provided with an insulating sheet, and the two brushes are spaced apart from the driving member and are respectively located on both sides of the insulating sheet.

[0014] In one embodiment, the pet-playing structure includes a fixing frame connected to the driving member. The fixing frame has a mounting portion, which forms two spaced-apart limiting grooves. An insulating portion is provided between the two limiting grooves, and each brush is limited to one of the limiting grooves.

[0015] In one embodiment, each of the limiting grooves has a positioning post on its bottom wall, each of the brushes has a positioning hole, and each positioning post is inserted into a positioning hole.

[0016] In one embodiment, the pet-playing structure includes a mounting frame, the mounting frame includes a mounting sleeve, the laser generator is disposed inside the mounting sleeve, and the mounting frame is connected to the output end of the driving component.

[0017] In one embodiment, the mounting bracket further includes a connecting sleeve, which is sleeved on the output end of the driving member, and a conductive sleeve is sleeved on the connecting sleeve. The connecting sleeve has two spaced wire grooves. A plurality of limiting blocks are spaced apart at the end of the connecting sleeve away from the driving member, and each limiting block abuts against the end of the conductive sleeve away from the driving member.

[0018] This utility model also proposes a recharge socket, comprising:

[0019] The housing has a mounting cavity and a through hole communicating with the mounting cavity;

[0020] The pet-teasing structure described in any of the above embodiments is disposed within the mounting cavity; and

[0021] A reflector assembly, wherein the reflector assembly is disposed in the housing and located within the mounting cavity;

[0022] The driving component drives the laser generator to move, so that the laser generator emits laser light to the reflector device and moves through the through hole on the ground.

[0023] In this technical solution, during the operation of the pet-teasing structure, an external power source provides power to the laser generator through brushes and conductive sleeves. The driving component drives the laser generator to rotate, causing the laser spot emitted by the generator to move rapidly across the ground, attracting pets to chase it and achieving the desired pet-teasing effect. The brush and conductive sleeve structure effectively reduces contact problems caused by wear, improves power supply stability, and thus enhances the reliability of the entire pet-teasing structure. During prolonged use, the laser generator receives a stable power supply, preventing laser interruptions or flickering due to unstable power supply, ensuring the normal operation of the pet-teasing toy. Because the brush and conductive sleeve materials have better wear resistance, component wear is reduced, extending the lifespan of the pet-teasing structure. Users do not need to frequently replace parts, reducing operating costs and maintenance workload. Stable power supply prevents the laser generator from suddenly stopping due to unstable power supply, reducing fright or injury to pets and enhancing the safety of the pet-teasing toy. Stable power supply and reliable structure ensure the continuous normal operation of the pet-teasing toy, providing a better entertainment experience for pets, while also reducing user frustration caused by equipment failure and improving the user experience. Attached Figure Description

[0024] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.

[0025] Figure 1 A schematic diagram of an embodiment of the pet-playing structure provided by this utility model;

[0026] Figure 2 An exploded structural diagram of an embodiment of the pet-teasing structure provided by this utility model;

[0027] Figure 3 A schematic diagram of an embodiment of the mounting bracket provided by this utility model;

[0028] Figure 4 A schematic diagram of a brush embodiment of this utility model is provided;

[0029] Figure 5 A schematic diagram of a fixing bracket embodiment of this utility model is provided;

[0030] Figure 6 A schematic diagram of a recharge base embodiment of this utility model is provided;

[0031] Figure 7 for Figure 6 A magnified view of part A in the middle.

[0032] Explanation of icon numbers:

[0033] 100. Pet-like structure; 1. Driving component; 2. Conductive assembly; 21. Conductive sleeve; 211. Insulating sheet; 22. Brush; 221. Connecting part; 222. Fork arm; 223. Support arm; 224. Contact part; 225. Positioning hole; 3. Laser generator; 4. Fixing frame; 41. Mounting part; 411. Limiting groove; 412. Insulating part; 413. Positioning post; 5. Mounting bracket; 51. Mounting sleeve; 52. Connecting sleeve; 521. Wire groove; 522. Limiting block;

[0034] 200, housing; 210, mounting cavity; 220, through hole; 300, reflector assembly.

[0035] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0036] 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 scope of protection of the present utility model.

[0037] It should be noted that if the embodiments of this utility model involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a specific posture. If the specific posture changes, the directional indicators will also change accordingly.

[0038] Furthermore, if the embodiments of this utility model involve descriptions such as "first" or "second," these descriptions are for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the use of "and / or" or "and / or" throughout the text includes three parallel solutions. For example, "A and / or B" includes solution A, solution B, or a solution where both A and B are satisfied simultaneously. Furthermore, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.

[0039] This utility model proposes a pet-teasing structure 100.

[0040] Please see Figure 1 In one embodiment of this utility model, the pet-playing structure 100 includes a driving component 1, a conductive component 2, and a laser generator 3. The conductive component 2 includes a conductive sleeve 21 and a brush 22. The conductive sleeve 21 is sleeved on the output end of the driving component 1, and the brush 22 is disposed on the driving component 1. The brush 22 and the conductive sleeve 21 are rotatably abutted against each other so that the brush 22 and the conductive sleeve 21 are electrically connected. The laser generator 3 is connected to the output end of the driving component 1 and is electrically connected to the conductive sleeve 21.

[0041] In this technical solution, during the operation of the pet-teasing structure 100, the external power supply provides power to the laser generator 3 through the brush 22 and the conductive sleeve 21. The driving component 1 drives the laser generator 3 to rotate, causing the laser spot emitted by the laser generator 3 to move rapidly on the ground, attracting the pet to chase and achieving the effect of pet-teasing. The structure employing brush 22 and conductive sleeve 21 effectively reduces contact problems caused by wear, improves power supply stability, and thus enhances the reliability of the entire pet-funny structure 100. During prolonged use, the laser generator 3 receives a stable power supply, preventing laser interruptions or flickering due to unstable power supply and ensuring normal operation of the pet-funny toy. Because the materials of brush 22 and conductive sleeve 21 have better wear resistance, component wear is reduced, extending the service life of the pet-funny structure 100. Users do not need to frequently replace parts, reducing operating costs and maintenance workload. Stable power supply prevents the laser generator 3 from suddenly stopping due to unstable power supply, reducing fright or injury to pets and enhancing the safety of the pet-funny toy. Stable power supply and reliable structure ensure the continuous normal operation of the pet-funny toy, providing a better entertainment experience for pets and reducing user annoyance caused by equipment failure, thus improving the user experience. In this design, the laser generator 3 and the conductive sleeve 21 are connected by wires. The driving component 1 drives the laser generator 3 and the conductive sleeve 21 to rotate synchronously, which will not cause the wires to become tangled, ensuring the stable operation of the equipment and further improving the reliability of the equipment and the user experience. At the same time, compared with the solution that uses a stylus and a ring-shaped printed circuit layer, and the stylus is set at one end of the turntable, resulting in uneven force between the stylus and the turntable, the conductive sleeve 21 and the brush 22 in this solution do not have the problem of uneven force, further improving the stability and reliability of the equipment.

[0042] Specifically, please refer to Figure 4In one embodiment, the brush 22 includes a connecting portion 221 and at least one fork arm 222. The connecting portion 221 is connected to the driving member 1 and the fork arm 222 respectively, and the fork arm 222 is rotatably abutting against the outer peripheral wall of the conductive sleeve 21. The brush 22 is a conductive component used to transfer electrical energy from a stationary part to a rotating part. The connecting part 221 is a part of the brush 22 structure, used to connect with the drive member 1 and the fork arm 222, serving to fix and conduct current. The fork arm 222 is a forked structure extending from the connecting part 221, contacting the conductive sleeve 21 for conducting current. The drive member 1 is an actuator that provides rotational power, which can be a motor or a cylinder, used to drive the laser generator 3 and the conductive sleeve 21 to rotate. The conductive sleeve 21 is a metal tubular structure sleeved on the output end of the drive member 1, used to receive current from the brush 22 and transmit it to the laser generator 3. The outer surface of the conductive sleeve 21 is the contact point of the brush 22 fork arm 222. The brush 22 is designed to consist of the connecting part 221 and one or more fork arms 222, with one end of the connecting part 221 fixed. Connected to the drive unit 1 to ensure that the brush 22 body has a stable position in the structure, the other end is connected to the fork arm 222. The fork arm 222 extends outward at a certain angle or tension, so that its end can actively approach the outer peripheral wall of the conductive sleeve 21. This structure allows the brush 22 to cross the space between the stationary and rotating parts to realize the physical conduction path of the current. When the drive unit 1 drives the conductive sleeve 21 to rotate, the fork arm 222 of the brush 22 always maintains contact with the outer peripheral wall of the conductive sleeve 21. Since the fork arm 222 can have a certain elasticity (such as using spring copper sheet or other materials), it can generate continuous pressure during rotation to achieve reliable electrical contact. The current is transmitted from the external power supply to the fork arm 222 through the connection part 221 of the brush 22, and then enters the conductive sleeve 21 through sliding contact with the conductive sleeve 21, and finally is transmitted to the laser generator 3. Throughout the process, the brush 22 body remains stationary, with only the fork arm 222 making sliding contact with the rotating conductive sleeve 21. This structure, by incorporating the fork arm 222 in the brush 22, allows the brush 22 to maintain continuous contact with the outer peripheral wall of the conductive sleeve 21 in a flexible manner. This ensures stable current delivery to the rotating component even as the drive component 1 rotates. Compared to the traditional contact method between the stylus and the metal ring, the fork arm 222 structure offers a larger contact area and superior self-adaptability, effectively mitigating wear caused by friction and reducing the risk of poor contact. The design of the connecting part 221 ensures the stability of the brush 22 within the overall structure, making the current transmission path reliable and enhancing the power supply continuity and structural durability of the laser pet-playing device during extended operation. This structural design balances electrical conductivity stability with the mechanical reliability of structural components, improving the overall lifespan and safety of the device.

[0043] Please see Figure 4In one embodiment, the brush 22 includes two forked arms 222, and the two ends of the connecting portion 221 are respectively connected to the two forked arms 222. The two forked arms 222 are rotatably abutted against the outer peripheral wall of the conductive sleeve 21, and the conductive sleeve 21 is located between the two forked arms 222. The two forked arms 222 refer to two conductive arms provided on the brush 22, which are usually symmetrically arranged to contact the conductive sleeve 21 simultaneously from two opposite directions, thereby improving conductivity reliability. The conductive sleeve 21 is sandwiched between the two forked arms 222, and the forked arms 222 contact the outer surface of the conductive sleeve 21 simultaneously from opposite sides. In this structure, each brush 22 consists of a connecting portion 221 and two forked arms 222 extending from its two ends, forming a U-shaped or clamp-like structure. The connecting portion 221 is located at the center of the structure, with one end fixedly connected to the drive member 1, so that the entire brush 22 assembly is held in a predetermined spatial position; the other end is connected to the two forked arms 222 respectively, so that the forked arms 222 can extend in two opposite directions respectively; the two forked arms 222 are spaced apart to simultaneously contact the surrounded conductive sleeve 21 from two directions; when the conductive sleeve 21 is fitted onto the output end of the drive member 1 and is between the two forked arms 222, the end of each forked arm 222 will naturally or elastically press against the outer peripheral wall of the conductive sleeve 21, forming two symmetrical sliding contact points. Thus, when the drive member 1 rotates and drives the conductive sleeve 21 to rotate, the two forked arms 222 can synchronously maintain contact with it, ensuring that the current is introduced into the conductive sleeve 21 from the connecting portion 221 through the two forked arms 222 respectively. The double-arm contact structure has symmetrical stability and can ensure normal conductivity of the other contact point even if the contact is poor due to friction, dust or other factors, thereby achieving high-reliability power supply. By setting two fork arms 222 and having them simultaneously abut against the outer wall of the conductive sleeve 21 from opposite sides, not only is the contact area between the brush 22 and the conductive component increased, but redundant conductive paths are also formed, effectively reducing the risk of single-point contact failure. This symmetrical enclosed structure also enhances the wrapping and limiting effect of the brush 22 on the conductive sleeve 21, preventing contact detachment due to vibration or speed fluctuations. Especially in situations with frequent rotation or long service life, the double fork arm 222 design can disperse wear pressure, improve the durability and stability of the overall structure, thereby ensuring that the laser generator 3 receives a continuous and stable power supply throughout the entire rotation process, thus improving the operational reliability and service life of the pet-playing device.

[0044] Further, please refer to Figure 4In one embodiment, each fork arm 222 includes two spaced-apart support arms 223, each support arm 223 having a contact portion 224 adapted to the outer peripheral wall of the conductive sleeve 21. The support arms 223 are further subdivided into the fork arms 222, and each fork arm 222 is composed of two spaced-apart support arms 223, effectively dividing the fork arm 222 into two branches. The contact portion 224 is located at the end of the support arm 223 and is used to form electrical contact with the outer peripheral wall of the conductive sleeve 21. The contact portion 224 matches the shape and position of the conductive sleeve 21, reliably achieving sliding contact without disengagement or poor contact. The arrangement of two support arms 223 in each fork arm 222, spaced apart, reduces the contact area between the fork arm 222 and the conductive sleeve 21, thereby reducing friction between the fork arm 222 and the conductive sleeve 21, reducing wear, and improving service life.

[0045] To ensure a more reliable electrical connection between the brush 22 and the conductive sleeve 21, please refer to [link / reference needed]. Figure 1 and Figure 2 In one embodiment, the conductive component 2 includes two brushes 22. An insulating sheet 211 is provided on the outer peripheral wall of the conductive sleeve 21. The two brushes 22 are spaced apart from the driving member 1 and located on opposite sides of the insulating sheet 211. The insulating sheet 211 divides the outer surface of the conductive sleeve 21 into two independent conductive areas. The two U-shaped brushes 22 are respectively located on the motor and on opposite sides of the insulating sheet 211. The two U-shaped brushes 22 are connected to the positive and negative terminals of an external power supply via wires, ensuring a stable power supply to the laser generator 3. The two brushes 22 are connected to the positive and negative terminals of an external power supply via external circuits, thereby supplying power to the two electrodes of the laser generator 3, forming a complete and safe closed circuit. This structure, by setting an insulating sheet 211 on the outer peripheral wall of the conductive sleeve 21 and arranging two brushes 22 on both sides of it, makes the contact between the brushes 22 and the conductive sleeve 21 more orderly and the electrical isolation clear, effectively avoiding the risk of short circuit caused by overlapping contact areas or sliding offset.

[0046] Furthermore, please refer to Figure 5In one embodiment, the pet-playing structure 100 includes a fixing frame 4 connected to the drive member 1. The fixing frame 4 has a mounting portion 41, which forms two spaced-apart limiting grooves 411. An insulating portion 412 is provided between the two limiting grooves 411, and each brush 22 is confined within one of the limiting grooves 411. The fixing frame 4 is a structural component for mounting, supporting, and positioning the drive member 1. The mounting portion 41 is a local area on the fixing frame 4, specifically used for mounting the brush 22. The limiting grooves 411 are groove structures formed in the mounting portion 41, used to limit the position of the brush 22 in the horizontal or radial direction, preventing it from shifting during operation. In the pet-playing structure 100, the brush 22 needs to be stably mounted near the drive system (i.e., the motor) to achieve reliable contact with the conductive sleeve 21. For this purpose, the system provides a fixing frame 4, which is mechanically connected to the motor as part of the overall structure, and also has a structure for mounting the brush 22—the mounting portion 41. The mounting section 41 has two spaced-apart limiting grooves 411, each groove 411 for accommodating and fixing one brush 22, ensuring its position does not shift due to vibration or rotation. An insulating section 412, made of electrically insulating material or coated with insulating material, is provided between the two limiting grooves 411 to prevent possible electrical connection between the two brushes 22. Each brush 22 is inserted into its corresponding limiting groove 411 and is positioned and constrained by three or four sides of the groove wall, thus maintaining stability in both the axial and radial directions. The brush 22 is fixed to the mounting frame 4 by interference fit, snap-fit, or screw fastening between the limiting groove 411 and the mounting frame 4, ensuring not only mechanical stability but also maintaining appropriate contact pressure during rotational contact. By providing two spaced-apart limiting grooves 411 on the mounting frame 4 and equipping it with an insulating section 412, this structure achieves dual stability for the brush 22 in both structural and electrical aspects. Structurally, the limiting groove 411 provides a clear and stable mounting position for the brush 22, preventing displacement or misalignment of the brush 22 due to vibration, temperature rise, or rotational inertia. Electrically, the insulating part 412 effectively blocks the possibility of conductivity between the two brushes 22, preventing short circuits or interference between the positive and negative terminals of the power supply. Overall, this structure ensures reliable contact and electrical safety between the brush 22 and the conductive sleeve 21, while improving the anti-interference capability, structural stability, and electrical reliability of the pet interaction structure 100 during long-term use. This structural form is particularly suitable for pet interaction devices that require continuous rotation and frequent operation.

[0047] To improve the installation stability of brush 22, please refer to [link / reference]. Figure 4 and Figure 5In one embodiment, each of the limiting grooves 411 has a positioning post 413 on its bottom wall, and each of the brushes 22 has a positioning hole 225. Each positioning post 413 is inserted into a positioning hole 225. The bottom wall refers to the supporting surface at the bottom of the limiting groove 411, i.e., the reference plane on which the brush 22 is placed. The positioning post 413 is a columnar structure protruding upward from the bottom wall of the limiting groove 411, used to insert into the positioning hole 225 on the brush 22 to ensure accurate positioning of the brush 22. The positioning hole 225 is a hole opened at the bottom or back of the brush 22 to cooperate with the positioning post 413 and prevent the brush 22 from rotating, sliding, or shifting. During the installation of the brush 22, in addition to the three-dimensional constraint of its external boundary by the limiting groove 411, a more refined structural positioning method—the cooperation between the positioning post 413 and the positioning hole 225—is used to enhance the installation accuracy and resistance to displacement. Specifically, a positioning post 413 is vertically installed on the bottom wall of each limiting groove 411. This post is generally cylindrical, conical, or has a snap-fit ​​structure. Simultaneously, the bottom of the brush 22 has a positioning hole 225 that matches its shape and size, serving as a plug-in interface. When the brush 22 is installed into the limiting groove 411, the positioning post 413 accurately inserts into the corresponding positioning hole 225, thus achieving precise positioning. This plug-in method not only prevents the brush 22 from sliding or shifting within the limiting groove 411 but also suppresses rotation or tilting caused by vibration or slight force during use. This plug-in structure also facilitates rapid alignment and automatic positioning of the brush 22 during assembly, improving assembly efficiency and consistency. Furthermore, it can be used in conjunction with snap-fit, threaded, or adhesive methods for further fixation. By setting the positioning post 413 on the bottom wall of the limiting groove 411 and forming a plug-in fit with the positioning hole 225 on the brush 22, this structure achieves precise positioning and anti-dislodgement / anti-shifting effects for the brush 22. Compared to relying solely on the sidewall of the limiting groove 411 for position restriction, the positioning post 413-positioning hole 225 structure provides higher positioning accuracy and anti-disturbance capability. Especially when there are adverse factors such as continuous vibration and rotational impact during the operation of the pet-playing device, it can effectively prevent the brush 22 from loosening or deviating in the groove, ensuring the contact stability between the brush 22 and the conductive sleeve 21. In addition, this structure has the advantages of convenient assembly and repeatable positioning during maintenance, which can reduce production errors, improve assembly consistency, and ultimately enhance the structural stability and power supply reliability of the entire pet-playing device.

[0048] Please see Figure 3In one embodiment, the pet-amusing structure 100 includes a mounting frame 5, which includes a mounting sleeve 51. The laser generator 3 is housed within the mounting sleeve 51, and the mounting frame 5 is connected to the output end of the drive component 1. The mounting frame 5 is a structural component used to mount and fix the laser generator 3, typically a mechanical support unit, serving a connection and positioning function. The mounting sleeve 51 is a component of the mounting frame 5, having a hollow cylindrical structure, used to accommodate the laser generator 3 and provide positioning protection. The laser generator 3 is the element that emits a visible laser spot and is the core output component of the pet-amusing device to attract the pet's attention. The output end of the drive component 1 refers to the rotation output part of the drive system (such as a motor), used to drive the connecting part 221 or the actuator to rotate. In this pet-amusing structure 100, to achieve the dynamic movement effect of the laser spot, the laser generator 3 needs to be connected to the drive component 1 so that it rotates synchronously with the output of the drive component 1. For this purpose, the system provides a mounting frame 5 as a connection intermediary, and the mounting sleeve 51 within it provides a space to accommodate the laser generator 3. The laser generator 3 is tightly mounted inside the mounting sleeve 51, which serves to fix, support, and protect the laser, preventing it from shaking or shifting during rotation. The entire mounting frame 5 is securely connected to the output end of the drive component 1 through structural fit, screws, snaps, or adhesives, thus maintaining synchronous rotation with the drive component 1. When the motor starts and the output shaft rotates, the mounting frame 5 and the laser generator 3 within it rotate together, causing the laser beam to form a continuously moving laser point on the ground, attracting pets to chase it, thereby achieving an automatic pet-playing function. This structural design ensures the stability and rotational accuracy of the laser during movement, avoiding problems such as spot deviation, discontinuity, or uneven movement. By placing the laser generator 3 inside the mounting sleeve 51 of the mounting frame 5 and connecting the mounting frame 5 to the output end of the drive component 1, a compact and mechanically coupled rotating laser projection system is constructed. This design not only ensures the positional stability of the laser generator 3 during rotation, preventing displacement or loosening due to vibration or rotational inertia, but also achieves consistency between the laser output direction and the drive direction, thereby ensuring that the laser spot can move on the ground in a continuous and controllable manner. Furthermore, the mounting sleeve 51 provides effective mechanical protection for the laser generator 3, enhancing the overall structural durability and safety, and enabling the pet-playing structure 100 to maintain good dynamic response and reliability during long-term operation.

[0049] Please see Figure 3In one embodiment, the mounting bracket 5 further includes a connecting sleeve 52, which is fitted onto the output end of the driving member 1. A conductive sleeve 21 is fitted onto the connecting sleeve 52. The connecting sleeve 52 has two spaced-apart wire-passing grooves 521. Multiple limiting blocks 522 are spaced apart at the end of the connecting sleeve 52 away from the driving member 1, and each limiting block 522 abuts against the end of the conductive sleeve 21 away from the driving member 1. The wire-passing groove 521 is a narrow, elongated slot on the connecting sleeve 52 for wires to pass through, preventing the rotating component from tangling or breaking the wires. The limiting block 522 is a small protrusion at the end of the connecting sleeve 52 away from the driving member 1, used to contact the end of the conductive sleeve 21 and restrict its axial movement. The end of the conductive sleeve 21 refers to the end of the conductive structure, which engages with the limiting block 522 to position and stabilize the conductive sleeve 21. When installing the laser generator 3 and the conductive structure, it is necessary to securely connect the output end of the drive unit 1 to each component and ensure that the wires can be smoothly led out. To this end, the mounting bracket 5 in the structure 100 is further provided with a connecting sleeve 52. This connecting sleeve 52 is hollow and entirely fitted outside the output end of the drive unit 1. It serves two purposes: supporting and connecting the mounting sleeve 51 and the drive unit 1, and also facilitating the wiring of electrical wires. To facilitate the passage of wires through the rotating structure without compression or tangling, the connecting sleeve 52 has two spaced-apart wire grooves 521, allowing the wires to smoothly enter the laser generator 3 from the conductive sleeve 21, maintaining circuit continuity. To further ensure the axial stability of the conductive sleeve 21 in the rotating structure, the connecting sleeve 52 has multiple spaced-apart limiting blocks 522 at the end away from the drive unit 1. These limiting blocks 522 are typically protruding and circumferentially distributed around the connecting sleeve 52, with their end faces physically contacting the end of the conductive sleeve 21 to prevent the conductive sleeve 21 from sliding along the output axis of the drive unit 1. This limiting structure prevents the conductive sleeve 21 from shifting due to centrifugal force, friction, or other factors during rotation or use, thereby maintaining reliable contact between the brush 22 and the conductive sleeve 21 and the structural stability of the entire system. By adding a connecting sleeve 52 to the mounting bracket 5, and combining it with the structural design of two wire channels 521 and multiple limiting blocks 522, the dual technical problems of wire lead-out and stable fixation of the conductive sleeve 21 in the rotating structure are solved. The wire channels 521 provide a clear wiring path, preventing damage to the wires due to friction or entanglement during rotation, and also facilitating maintenance and replacement; the limiting blocks 522 abut against the end of the conductive sleeve 21, effectively limiting the axial displacement of the conductive sleeve 21, preventing it from shifting during high-speed rotation or long-term operation, ensuring continuous contact between the brush 22 and the conductive surface, and providing space for the wires in the wire channels 521 to extend. The overall structure improves the safety, reliability, and service life of the pet-playing device in terms of electrical power supply and mechanical linkage, providing solid support for the long-term stable operation of the pet interaction equipment.

[0050] This utility model also proposes a rechargeable base, which includes a housing 200, a reflector device 300, and a pet-playing structure 100. The specific structure of the pet-playing structure 100 is as described in the above embodiments. Since this rechargeable base adopts all the technical solutions of all the above embodiments, it has at least all the beneficial effects brought about by the technical solutions of the above embodiments, and will not be described in detail here. The housing 200 has a mounting cavity 210 and a through hole 220 communicating with the mounting cavity 210; the pet-playing structure 100 is disposed within the mounting cavity 210; the reflector device 300 is disposed within the housing 200 and located within the mounting cavity 210; the driving member 1 drives the laser generator 3 to move, so that the laser generator 3 emits laser light towards the reflector device 300 and moves on the ground through the through hole 220.

[0051] Please see Figure 6 and Figure 7 In this embodiment, the housing 200 is made of a sturdy and durable plastic material, providing good protection and portability. An installation cavity 210 is provided inside the housing 200 to accommodate the pet-playing structure 100 and the reflector device 300. A through hole 220 communicating with the installation cavity 210 is also provided on the surface of the housing 200, allowing the laser to pass through and form a moving light spot on the ground to attract the pet to chase it. The reflector device 300 is located inside the installation cavity 210 of the housing 200, above the pet-playing structure 100. The reflector device 300 includes one or more reflectors, the angles and positions of which can be adjusted as needed to ensure that the laser is reflected along a predetermined path and moves across the ground through the through hole 220. The function of the reflector device 300 is to reflect and guide the laser emitted by the laser generator 3, causing it to form one or more moving light spots on the ground, increasing the fun and interactivity of the pet-playing activity. Simultaneously, the recharge base includes a lens that passes through the through hole 220 and is connected to the housing 200. The lens protects against dust and other impurities from entering the mounting cavity 210, helping to extend the lifespan of the device and reduce maintenance costs. The charging dock has the function of charging the robot vacuum cleaner, and for pet-owning families, the charging dock integrates a pet-entertaining structure 100, which can achieve the purpose of interacting with pets.

[0052] The above description is merely an exemplary embodiment of the present utility model and does not limit the patent scope of the present utility model. Any equivalent structural transformations made based on the technical concept of the present utility model and the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the patent protection scope of the present utility model.

Claims

1. A pet teasing structure, characterized by, include: Drive components; A conductive component, comprising a conductive sleeve and a brush, wherein the conductive sleeve is sleeved on the output end of the driving member, the brush is disposed on the driving member, and the brush and the conductive sleeve are rotatably abutted against each other to make the brush and the conductive sleeve electrically connected; as well as A laser generator is connected to the output end of the drive unit and electrically connected to the conductive sleeve.

2. The pet teasing structure of claim 1, wherein, The brush includes a connecting part and at least one fork arm. The connecting part is connected to the driving member and the fork arm respectively. The fork arm is rotatably abutting against the outer peripheral wall of the conductive sleeve.

3. The pet-playing structure as described in claim 2, characterized in that, The brush includes two forked arms, and the two ends of the connecting part are respectively connected to the two forked arms. The two forked arms are rotatably abutted against the outer peripheral wall of the conductive sleeve, and the conductive sleeve is located between the two forked arms.

4. The pet-playing structure as described in claim 3, characterized in that, Each of the fork arms includes two spaced-apart support arms, and each support arm has a contact portion adapted to the outer peripheral wall of the conductive sleeve.

5. The pet-amusing structure as described in any one of claims 1 to 4, characterized in that, The conductive component includes two brushes. The outer peripheral wall of the conductive sleeve is provided with an insulating sheet. The two brushes are spaced apart from the driving member and are respectively located on both sides of the insulating sheet.

6. The pet-playing structure as described in claim 5, characterized in that, The pet-playing structure includes a fixing frame connected to the driving component. The fixing frame has a mounting part, which forms two spaced-apart limiting grooves. An insulating part is provided between the two limiting grooves, and each brush is limited to one of the limiting grooves.

7. The pet-playing structure as described in claim 6, characterized in that, Each of the limiting grooves has a positioning post on its bottom wall, each of the brushes has a positioning hole, and each positioning post is inserted into a positioning hole.

8. The pet-teasing structure as described in any one of claims 1 to 4, characterized in that, The pet-playing structure includes a mounting frame, which includes a mounting sleeve. The laser generator is located inside the mounting sleeve, and the mounting frame is connected to the output end of the driving component.

9. The pet-playing structure as described in claim 8, characterized in that, The mounting bracket further includes a connecting sleeve, which is sleeved on the output end of the drive component. A conductive sleeve is sleeved on the connecting sleeve. The connecting sleeve has two spaced wire grooves. A plurality of limiting blocks are spaced apart on the end of the connecting sleeve away from the drive component. Each limiting block abuts against the end of the conductive sleeve away from the drive component.

10. A rechargeable socket, characterized in that, include: The housing has a mounting cavity and a through hole communicating with the mounting cavity; The pet-teasing structure as described in any one of claims 1 to 9, wherein the pet-teasing structure is disposed within the mounting cavity; and A reflector assembly, wherein the reflector assembly is disposed in the housing and located within the mounting cavity; in, The driving component drives the laser generator to move, so that the laser generator emits laser light to the reflector device and moves through the through hole on the ground.