Fly-away fan
The fly-repelling fan, powered by solar energy and featuring a split-structure design, solves the problems of inconvenient power supply and insufficient structural protection, enabling continuous operation and efficient fly repellency while reducing operating costs and maintenance frequency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHENZHEN KEEWAY TECH CO LTD
- Filing Date
- 2025-06-12
- Publication Date
- 2026-06-05
AI Technical Summary
Existing fly-repelling fans suffer from inconvenient power supply methods, requiring frequent battery replacements or recharging, and their structural design suffers from insufficient protection and limited control functions.
The system employs a solar power supply system, combined with a split structure and intelligent charging and discharging management. It uses solar panels to convert light energy into electrical energy, which is then stabilized and stored by control components to drive the reflective fan blades to rotate. The connecting pipes use a flexible protective layer and a composite fixing method to enhance the equipment's protection and convenience.
This enables continuous operation of the equipment, reduces operating costs and maintenance frequency, improves the stability and fly-repelling efficiency of the equipment in outdoor environments, simplifies control operations, and extends the service life of the equipment.
Smart Images

Figure CN224320106U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of fan technology, and in particular to a fly-repelling fan. Background Technology
[0002] Currently, most fly-repelling fans on the market achieve their fly-repelling effect by using a motor to drive reflective blades to generate dazzling light. These products generally suffer from inconvenient power supply options: those powered by dry-cell batteries require frequent battery replacements, increasing operating costs and wasting resources; while those with built-in rechargeable lithium batteries avoid the hassle of battery replacements, they still require frequent charging when multiple devices are used simultaneously, impacting usability. Furthermore, the structural design of existing fly-repelling fans has room for improvement, such as insufficient protection of connecting components and limited control functions.
[0003] To address the aforementioned issues, existing technologies urgently need improvement. Utility Model Content
[0004] The main purpose of this invention is to propose a fly-repelling fan that has the advantages of using solar power to reduce battery dependence, high structural protection, and convenient control.
[0005] To achieve the above objectives, the fly-repelling fan proposed in this utility model includes:
[0006] A base, wherein a receiving cavity is formed inside the base, and a mounting groove is provided at the top of the base;
[0007] A solar panel, wherein the solar panel is installed in the mounting groove;
[0008] A drive assembly, comprising a drive component and a mounting base, wherein the mounting base has a mounting cavity and the drive component is disposed within the mounting cavity;
[0009] A connecting tube, the bottom end of which extends into the receiving cavity and the top end of which extends into the mounting cavity, wherein the connecting tube is a hollow tube;
[0010] A control component is disposed within the receiving cavity and electrically connected to the solar panel and the driving component, respectively;
[0011] Reflective fan blades, the output shaft of the drive unit is connected to the reflective fan blades.
[0012] In one embodiment, the base includes an upper base cover and a lower base cover that are connected to each other, the upper base cover and the lower base cover forming the receiving cavity, the upper base cover having the mounting groove, and the upper base cover also having a first mounting hole, the bottom end of the connecting tube passing through the first mounting hole and extending into the receiving cavity.
[0013] In one embodiment, the mounting base includes an upper mounting base cover and a lower mounting base cover connected to each other, the upper mounting base cover and the lower mounting base cover forming the mounting cavity, the lower mounting base cover having a second mounting hole, the top end of the connecting tube passing through the second mounting hole and extending into the mounting cavity, the upper mounting base cover having a third mounting hole, the output shaft of the drive unit passing through the third mounting hole and connecting to the reflective fan blade.
[0014] In one embodiment, the fly-repellent fan further includes an upper cover and a lower cover, the reflective blade is installed between the upper cover and the lower cover, the upper cover is also provided with a fourth mounting hole, and the output shaft of the drive unit passes through the lower cover and the blade in sequence and extends into the fourth mounting hole.
[0015] In one embodiment, the connecting pipe includes a pipe body and a flexible protective layer. The pipe body is a hollow pipe, and the flexible protective layer covers the pipe body. The bottom end of the pipe body extends into the receiving cavity, and the top end of the pipe body extends into the mounting cavity.
[0016] In one embodiment, the control component includes a battery pack and a circuit board, the circuit board being electrically connected to the solar panel, the battery pack, and the drive unit, respectively.
[0017] In one embodiment, the fly-repelling fan further includes a display screen and a control switch. The display screen is installed in the mounting slot and abuts against the solar panel, and the control switch is located near the display screen and electrically connected to the circuit board.
[0018] In one embodiment, a power interface is also provided on the outer wall of the base, and the power interface is connected to the control board.
[0019] In one embodiment, the surface of the reflective fan blades is coated with a laser film.
[0020] In one embodiment, the fly-repelling fan further includes a plurality of support feet, which are spaced apart and installed at the bottom end of the base.
[0021] The technical solution of this utility model achieves solar power supply through the cooperation of solar panels and control components, reducing the frequency of battery replacement; the connecting pipe adopts a flexible protective layer to improve protection, and the split structure of the mounting base and the base facilitates maintenance, which has the advantages of reducing the cost of use and improving convenience. Attached Figure Description
[0022] 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.
[0023] Figure 1 A three-dimensional structural diagram of the fly-repelling fan provided by this utility model at one angle;
[0024] Figure 2 A cross-sectional view of the fly-repelling fan provided by this utility model;
[0025] Figure 3 This is an exploded structural diagram of the fly-repelling fan provided by this utility model.
[0026] Explanation of icon numbers:
[0027] 100. Fly-repellent fan; 1. Base; 11. Receiving cavity; 12. Mounting slot; 2. Solar panel; 3. Drive assembly; 31. Drive component; 32. Mounting base; 321. Mounting cavity; 4. Connecting pipe; 5. Control assembly; 6. Reflective fan blades; 13. Base upper cover; 14. Base lower cover; 131. First mounting hole; 322. Mounting base upper cover; 323. Mounting base lower cover; 3231. Second mounting hole; 3221. Third mounting hole; 7. Fan blade upper cover; 8. Fan blade lower cover; 71. Fourth mounting hole; 41. Pipe body; 42. Flexible protective layer; 51. Battery pack; 52. Circuit board; 9. Display screen; 91. Control switch; 92. Power interface; 93. Support foot.
[0028] 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
[0029] 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.
[0030] 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.
[0031] 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.
[0032] In existing technologies, fly-repellent fans are typically powered by dry cell batteries or rechargeable lithium batteries, which suffers from frequent battery replacements, high operating costs, and inconvenient charging. When used outdoors, these devices often fail to repel flies due to power outages, affecting their effectiveness. For example, in scenarios such as farms or open-air restaurants, multiple devices operating simultaneously accelerate battery consumption, requiring maintenance personnel to frequently check the device's battery status.
[0033] This utility model proposes a fly-repelling fan.
[0034] Please see Figures 1 to 3 In one embodiment of this utility model, the fly-repelling fan 100 includes a base 1, a solar panel 2, a connecting pipe 4, a control component 5, and reflective fan blades 6. The base 1 forms a receiving cavity 11, and the top of the base 1 has an installation groove 12. The solar panel 2 is installed in the installation groove 12. The drive component 31 includes a drive member 31 and a mounting base 32. The mounting base 32 has an installation cavity 321, and the drive member 31 is disposed in the installation cavity 321. The bottom end of the connecting pipe 4 extends into the receiving cavity 11, and the top end of the connecting pipe 4 extends into the installation cavity 321. The connecting pipe 4 is a hollow pipe. The control component 5 is disposed in the receiving cavity 11 and is electrically connected to the solar panel 2 and the drive member 31 respectively. The output shaft of the drive member 31 is connected to the reflective fan blades 6.
[0035] The base 1 is the foundation supporting the main structure of the equipment, which can be formed by splicing together a split injection-molded shell. Its cavity 11 is used to install the control circuit and energy storage unit. The solar panel 2 is a photovoltaic conversion device, which can be a monocrystalline silicon module embedded in the top of the base 1 to convert light energy into electrical energy. The drive component 3 includes a motor and a fixing bracket. The connecting pipe 4 is a tubular component that runs through the structure, realizing the dual functions of power transmission and structural support. The control component 5 includes a charge / discharge management module, integrating voltage conversion and energy storage control functions via a circuit board. The reflective fan blade 6 is a surface-treated optical device that produces a dynamic reflective effect through rotation.
[0036] Specifically, solar panel 2 generates electricity under sunlight and is electrically connected to control component 5 via wires. Control component 5 regulates the voltage of the electricity and stores it in the battery cell, while simultaneously supplying power to drive component 3 according to a set program. When drive component 31 rotates reflective fan blades 6, their surface is covered with a laser film to interfere with insect visual perception. Connecting pipe 4 serves as a structural support, maintaining the mechanical connection between base 1 and drive component 3 while also providing protection for internal wiring. The tilt angle design of mounting slot 12 allows solar panel 2 to achieve the optimal light-receiving angle, and the internal space partitioning design of base 1 avoids electromagnetic interference.
[0037] Compared with existing technologies, this solution replaces traditional batteries with a solar power system, eliminating the need for regular battery replacements. The integrated design of the control component 5 simplifies the circuit layout and reduces the probability of failure. The connecting pipe 4 is a hollow pipe; specifically, the connecting pipe 4 can be a hollow rigid pipe or a flexible universal tube. In this embodiment, the connecting pipe 4 is preferably a flexible universal tube. The connecting pipe 4 made of a flexible universal tube can be bent to change the orientation of the reflective fan blade 6 connected above the connecting pipe 4, thereby changing the overall orientation of the fly-repelling fan 100. Furthermore, the use of a flexible universal tube 4 also makes the fly-repelling fan 100 in this embodiment easy to bend and store. The direct connection between the reflective fan blade 6 and the drive component 3 reduces energy loss and improves fly-repelling efficiency.
[0038] Through the above technical solutions, this application enables the equipment to operate continuously without an external power source, reducing operating costs and maintenance frequency. The coordinated design of the solar power supply system and mechanical structure ensures stable operation of the equipment in outdoor environments, and the specific processing technology of the reflective fan blades 6 enhances the optical deflection effect. The intelligent charging and discharging management of the control component 5 extends the service life of the equipment, and the composite functional design of the connecting pipe 4 improves the overall structural reliability.
[0039] In one embodiment, the base 1 includes an upper base cover 13 and a lower base cover 14 connected to each other. The upper base cover 13 and the lower base cover 14 form a receiving cavity 11. The upper base cover 13 has an installation groove 12 and a first installation hole 131. The bottom end of the connecting pipe 4 passes through the first installation hole 131 and extends into the receiving cavity 11.
[0040] The upper base cover 13 and the lower base cover 14 are detachably connected to form a sealed receiving cavity 11, allowing internal components such as the control assembly 5 and the battery pack 51 to be installed in stages. The mounting groove 12 is formed simultaneously with the upper base cover 13 during molding, providing a precise mounting reference surface for the solar panel 2. The first mounting hole 131 is perpendicularly through the contact area between the upper base cover 13 and the connecting pipe 4, ensuring that the bottom end of the connecting pipe 4 can directly extend into the receiving cavity 11 to dock with the control assembly 5. The split base 1 structure allows the internal wiring to be arranged before the outer casing is encapsulated during assembly, avoiding assembly interference problems caused by traditional integrated structures.
[0041] In one embodiment, the mounting base 32 includes an upper mounting base cover 322 and a lower mounting base cover 323 connected to each other. The upper mounting base cover 322 and the lower mounting base cover 323 form a mounting cavity 321. The lower mounting base cover 323 has a second mounting hole 3231. The top end of the connecting pipe 4 passes through the second mounting hole 3231 and extends into the mounting cavity 321. The upper mounting base cover 322 has a third mounting hole 3221. The output shaft of the drive member 31 passes through the third mounting hole 3221 and connects to the reflective fan blade 6.
[0042] The second mounting hole 3231 is a circular through hole located at the center of the lower cover 323 of the mounting base. A nut can be installed inside the lower cover 323 to achieve a threaded connection with the connecting pipe 4. In other embodiments, the diameter of the second mounting hole can be slightly smaller than the outer diameter of the connecting pipe 4. Specifically, an interference fit can be used to fix the top of the connecting pipe 4 after insertion. The third mounting hole 3221 is a mounting hole opened in the upper cover 322 of the mounting base to allow the output shaft of the drive component 31 to pass through. The diameter of the third mounting hole 3221 is larger than the output shaft of the drive component 31 to prevent interference with the output shaft. The upper cover 322 and the lower cover 323 of the mounting base are connected to form a sealed space to prevent external dust from entering and affecting the operation of the drive component 31.
[0043] In one embodiment, the fly-repelling fan 100 further includes an upper cover 7 and a lower cover 8, with reflective blades 6 installed between the upper cover 7 and the lower cover 8. The upper cover 7 also has a fourth mounting hole 71, and the output shaft of the drive unit 31 passes through the lower cover 8 and the blades in sequence and extends into the fourth mounting hole 71.
[0044] The upper cover 7 of the fan blade refers to the shell component covering the top of the reflective fan blade 6, which can be made of injection-molded plastic and is used to cooperate with the lower cover 8 of the fan blade to form a clamping space. The lower cover 8 of the fan blade refers to the shell component located at the bottom of the reflective fan blade 6, which can be implemented with a structure symmetrical to the upper cover 7 of the fan blade. The fourth mounting hole 71 refers to the through hole opened in the center of the upper cover 7 of the fan blade, which can be implemented with a circular hole structure. The hole diameter is slightly larger than the diameter of the output shaft of the drive component 31. The fourth mounting hole 71 can be a threaded hole, which can be fixed to the output shaft of the drive component 31 by threaded connection. In other embodiments, the fourth mounting hole 71 and the output shaft of the drive component 31 can also be made with an interference fit. Specifically, the diameter of the output shaft of the drive component 31 can be slightly larger than the diameter of the fourth mounting hole 71. The output shaft of the drive component 31 is inserted into the fourth mounting hole 71 to make the output shaft of the drive component 31 and the fourth mounting hole 71 have an interference fit.
[0045] Specifically, the reflective fan blade 6 is clamped between the upper fan blade cover 7 and the lower fan blade cover 8, forming a mechanical fixation through their tight fit. The output shaft of the drive unit 31 enters from the bottom of the lower fan blade cover 8, passes through the lower fan blade cover 8 and the reflective fan blade 6 in sequence, and then embeds into the fourth mounting hole 71 of the upper fan blade cover 7. This multi-layer through-hole structure enables the drive shaft and the reflective fan blade 6 to be axially positioned.
[0046] Compared to existing technologies, current fly-repellent fans typically use a single-layer cover to fix the fan blades or directly attach the fan blades to the drive shaft. Such structures are prone to problems such as fan blade loosening and coating peeling during long-term high-speed operation. This solution uses a composite fixing method of double-layer cover clamping and axial through-positioning to form a self-locking structure for the fan blade assembly, thus solving the defect of easy failure of a single fixing point.
[0047] In one embodiment, the connecting pipe 4 includes a pipe body 41 and a flexible protective layer 42. The pipe body 41 is a hollow pipe, and the flexible protective layer 42 covers the outside of the pipe body 41. The bottom end of the pipe body 41 extends into the receiving cavity 11, and the top end of the pipe body 41 extends into the mounting cavity 321.
[0048] In this embodiment, the tube body 41 refers to a rigid support component with a hollow structure. Specifically, it can be a flexible, universal shaped hose, which can be bent to change the orientation of the reflective fan blades 6 connected to the connecting tube 4, thereby changing the overall orientation of the fly-repelling fan 100. Furthermore, the universal hose connecting tube 4 makes the fly-repelling fan 100 easy to bend and store. The flexible protective layer 42 refers to an elastic material layer covering the outside of the tube body 41, which can be made of silicone. By wrapping the tube body 41, it forms a buffer interface to absorb external impact energy. Specifically, the tube body 41, through its hollow structure, maintains its rigidity while providing a transmission path for the wiring connection or heat dissipation airflow between the control component 5 and the drive component 3. The flexible protective layer 42, through its elastic deformation characteristics, disperses stress when the connecting tube 4 is subjected to external pressure or vibration, preventing the rigid tube body from directly bearing the impact.
[0049] In one embodiment, the control component 5 includes a battery pack 51 and a circuit board 52, which is electrically connected to the solar panel 2, the battery pack 51, and the drive unit 31. The battery pack 51 is a device for storing electrical energy, specifically a lithium-ion battery. Through its electrical connection to the circuit board 52, the battery pack 51 provides stable and reliable power to the circuit board 52, and the circuit board 52 also controls the discharge of the battery pack. The solar panel 2 is electrically connected to the circuit board 52, providing current to it, and the circuit board 52 controls the regulation of electrical energy output and the start / stop of the drive unit 31. Specifically, the solar panel 2 converts light energy into electrical energy under sunlight and transmits it to the battery pack 51 for storage via wires. The circuit board 52 continuously monitors the energy storage status of the battery pack 51 through preset circuit logic. When the stored energy reaches a set threshold, the circuit board 52 distributes the electrical energy to the drive unit 31 to maintain the rotation of the reflective fan blades 6. When insufficient sunlight causes the battery pack 51 to store less than a threshold amount of electricity, the circuit board 52 can cut off the power supply to the drive unit 31 to prevent over-discharge of the battery. Thus, the solar power system forms a closed-loop control system, eliminating the need for external power sources or frequent battery replacements.
[0050] Compared to existing technologies, traditional fly-repellent fans using dry cell batteries require regular battery replacements, while those with built-in lithium batteries require frequent charging. Both suffer from high operating costs and inconvenient maintenance. This solution integrates solar panel 2 and battery pack 51 to convert ambient light energy into a continuous power supply. Simultaneously, circuit board 52 enables automated management of energy storage and distribution, significantly reducing reliance on manual intervention.
[0051] In one embodiment, the fly-repellent fan 100 further includes a display screen 9 and a control switch 91. The display screen 9 is installed in the mounting groove 12 and abuts against the solar panel 2. The control switch 91 is located near the display screen 9 and is electrically connected to the circuit board 52. The display screen 9 is an electronic component used to display the operating status of the device. Specifically, it can be an LCD screen, an LED screen, or a 188 digital tube covered with a semi-transparent plastic part to achieve the display effect. It visualizes battery power and working mode information through electrical signal conversion. The control switch 91 is an operating component used to start or stop the device or switch functions. Specifically, it can be implemented using mechanical buttons or a touch sensor. It controls the working status of the drive component 3 through circuit switching. The mounting groove 12 is a recessed structure at the top of the base 1 for accommodating the solar panel 2. By embedding the display screen 9 into this groove and making physical contact with the solar panel 2, space reuse and power supply stability are achieved. The circuit board 52 is an electronic module that integrates control circuitry. It connects the display screen 9 with wires to transmit data signals and receive commands from the control switch 91. Through the above technical solution, this application achieves real-time visual feedback of the device's operating status, allowing users to grasp battery power and working mode information without the need for external tools. The proximity of the control switch 91 and the display screen 9 makes one-handed operation possible, reducing eye movement and action steps.
[0052] In one embodiment, a power interface 92 is also provided on the outer wall of the base 1, and the power interface 92 is connected to the circuit board 52. The power interface 92 is a physical port located on the outer wall of the base 1 for connecting to an external power source. Specifically, it can be a Type-C interface, a USB interface, or a DC jack, and its function is to provide an external power input path for the battery pack 51. The battery pack 51 is an energy storage unit integrated within the receiving cavity 11, and can be a rechargeable lithium battery pack or a nickel-metal hydride battery pack. Its function is to store and release electrical energy through bidirectional connection with the circuit board 52 and the power interface 92.
[0053] Specifically, when the power supply capacity of the solar panel 2 decreases due to insufficient sunlight, the power interface 92 is configured to connect to the mains power or a power bank via an external power cable. At this time, external power is transmitted to the battery pack 51 for charging through the power interface 92. When the battery pack 51 has sufficient power, power is continuously supplied to the drive component 3 through the circuit board 52 to maintain the fly-repelling function of the reflective fan blades 6. This structure allows the equipment to be continuously powered by an external power source when solar power is limited, avoiding equipment downtime due to reliance on a single energy source.
[0054] In one embodiment, the surface of the reflective fan blade 6 is coated with a laser film. By utilizing the high reflectivity of the laser film, the vision of flies can be effectively interfered with, making it difficult for them to stay near the fly-repelling fan, thereby improving fly-repelling efficiency. In addition, the wear-resistant and corrosion-resistant properties of the laser film can protect the surface of the reflective fan blade 6 and extend its service life.
[0055] Compared to existing technologies, traditional metal fan blades are prone to electrochemical corrosion in humid environments, leading to plating peeling, while plastic substrates fundamentally eliminate the problem of metal corrosion. Conventional mirror plating produces excessively high intensity directional reflected light, while matte silver plating creates a more uniform and durable diffuse reflected light field.
[0056] This application further proposes that the fly-repelling fan 100 also includes support feet 93, and the number of support feet 93 is multiple and they are installed at intervals at the bottom end of the base 1.
[0057] The support feet 93 are components installed at the bottom of the base 1 to provide contact support. They can be made of rubber, silicone, or hard plastic materials, and increase the friction between the base 1 and the contact surface to prevent slippage. The spaced installation means that multiple support feet 93 are arranged in a ring or symmetrical distribution at the bottom of the base 1. They can be fixed by snap-fit, threaded connection, adhesive, or integral molding. In this embodiment, the support feet 93 are preferably installed at the bottom of the base 1 by adhesive bonding, forming a multi-point support structure to distribute the weight of the equipment.
[0058] Through the above technical solution, this application solves the problem of insufficient stability of the fly repellent fan 100 when placed, ensuring stable support of the device on smooth tabletops or inclined ground, while adapting to the slippery surface conditions caused by rain or dew in outdoor humid environments, and avoiding the risk of tipping over due to external impact or its own vibration.
[0059] The above are merely exemplary embodiments of this utility model and do not limit the patent scope of this utility model. Any equivalent structural transformations made based on the technical concept of this utility model and the contents of the specification and drawings of this utility model, or direct / indirect applications in other related technical fields, are included within the patent protection scope of this utility model.
Claims
1. A fly-repelling fan, characterized in that, The fly-repellent fan includes: A base, wherein a receiving cavity is formed inside the base, and a mounting groove is provided at the top of the base; A solar panel, wherein the solar panel is installed in the mounting groove; A drive assembly, comprising a drive component and a mounting base, wherein the mounting base has a mounting cavity and the drive component is disposed within the mounting cavity; A connecting tube, the bottom end of which extends into the receiving cavity and the top end of which extends into the mounting cavity, wherein the connecting tube is a hollow tube; A control component is disposed within the receiving cavity and electrically connected to the solar panel and the driving component, respectively; Reflective fan blades, the output shaft of the drive unit is connected to the reflective fan blades.
2. The fly-repelling fan as described in claim 1, characterized in that, The base includes an upper base cover and a lower base cover that are connected to each other. The upper base cover and the lower base cover form the receiving cavity. The upper base cover has the mounting groove and a first mounting hole. The bottom end of the connecting tube passes through the first mounting hole and extends into the receiving cavity.
3. The fly-repelling fan as described in claim 2, characterized in that, The mounting base includes an upper mounting base cover and a lower mounting base cover connected to each other. The upper mounting base cover and the lower mounting base cover form the mounting cavity. The lower mounting base cover has a second mounting hole. The top end of the connecting tube passes through the second mounting hole and extends into the mounting cavity. The upper mounting base cover has a third mounting hole. The output shaft of the drive unit passes through the third mounting hole and connects to the reflector blade.
4. The fly-repelling fan as described in claim 3, characterized in that, The fly-repellent fan also includes an upper cover for the fan blades and a lower cover for the fan blades. The reflective fan blades are installed between the upper cover for the fan blades and the upper cover for the fan blades. The upper cover for the fan blades also has a fourth mounting hole. The output shaft of the drive unit passes through the lower cover for the fan blades and the fan blades in sequence and extends into the fourth mounting hole.
5. The fly-repelling fan as described in claim 1, characterized in that, The connecting pipe includes a pipe body and a flexible protective layer. The pipe body is a hollow pipe, and the flexible protective layer covers the pipe body. The bottom end of the pipe body extends into the receiving cavity, and the top end of the pipe body extends into the mounting cavity.
6. The fly-repelling fan as described in claim 1, characterized in that, The control component includes a battery pack and a circuit board, the circuit board being electrically connected to the solar panel, the battery pack, and the drive unit, respectively.
7. The fly-repelling fan as described in claim 6, characterized in that, The fly-repelling fan also includes a display screen and a control switch. The display screen is installed in the mounting slot and abuts against the solar panel. The control switch is located near the display screen and is electrically connected to the circuit board.
8. The fly-repelling fan as described in claim 6, characterized in that, The outer wall of the base is also provided with a power interface, which is connected to the control board.
9. The fly-repelling fan as described in any one of claims 1 to 8, characterized in that, The surface of the reflective fan blades is covered with a laser film.
10. The fly-repelling fan as described in any one of claims 1 to 7, characterized in that, The fly-repelling fan also includes multiple support feet, which are spaced apart and installed at the bottom of the base.