Indoor mosquito trap with a biomimetic structure of a pitcher plant

Abstract

The utility model relates to mosquito trapper technical field, and disclose the indoor mosquito trapper of bionic nepenthes structure, including trapper shell : including trapper shell : the top end rotation of trapper shell is connected with electric rotation top cover, the inside fixed connection of trapper shell has fixed ring, the bottom of fixed ring installs mosquito trapper subassembly, the front end of trapper shell is set up and placed groove, the inside slide connection of placed groove has the storage box, the front fixed connection of storage box has fixed plate. The indoor mosquito trapper of bionic nepenthes structure, through can the setting of convenient fixed storage box, when trapper shell can stably fixed in the inside of trapper shell during the use of trapper shell, and then effectively prevent the dump of trapper shell to cause the storage box to slide out, thereby avoided the condition of mosquito cadaver falling to outside to cause secondary pollution, effectively promoted practicality.

Description

Technical Field

[0001] This utility model relates to the field of mosquito trap technology, and in particular to an indoor mosquito trap with a biomimetic pitcher plant structure. Background Technology

[0002] Mosquito traps are devices that attract, capture, or kill mosquitoes by mimicking their ecological needs through physical, chemical, or biological means. Pitcher plants have a unique pitcher-like structure, and their pitchers are usually cylindrical with a slightly enlarged lower half and a lid on the opening. Mosquito traps that mimic the structure of pitcher plants will imitate this pitcher-like shape in appearance, using a similar cylindrical design to provide a similar visual and spatial experience, making it easier for mosquitoes to be attracted into the trap.

[0003] Currently, indoor mosquito traps with a biomimetic pitcher plant structure are typically secured by snap-fit ​​mechanisms. When the device is impacted and tipped over, the trap can easily slip out, causing dead mosquitoes to spill out and resulting in secondary pollution. Utility Model Content

[0004] The technical problem this invention aims to solve is that existing mosquito traps are prone to slipping out due to external contact, which can lead to bacterial growth. To address this, we propose an indoor mosquito trap with a biomimetic pitcher plant structure.

[0005] To achieve the above objectives, this application adopts the following technical solution: an indoor mosquito trap with a biomimetic pitcher plant structure, comprising a trap shell: an electrically rotating top cover is rotatably connected to the top of the trap shell; a fixing ring is fixedly connected inside the trap shell; a mosquito trapping component is installed at the bottom of the fixing ring; a placement groove is opened at the front end of the trap shell; a storage box is slidably connected inside the placement groove; a fixing plate is fixedly connected to the front end of the storage box; a limit rod is slidably connected inside the fixing plate; a push-pull plate is fixedly connected to the top of the limit rod; a connecting plate is fixedly connected to the front end of the trap shell; a limit hole is opened on the surface of the connecting plate; and the interior of the limit hole is slidably connected to the limit rod.

[0006] Preferably, a spring is sleeved on the surface of the limiting rod, and the top and bottom ends of the spring are fixedly connected to the fixing plate and the push-pull plate, respectively.

[0007] Preferably, the inner diameter of the limiting hole is designed to match the size of the limiting rod.

[0008] Preferably, the top of the trap shell is equipped with a honey gland bionic groove, and the inside of the honey gland bionic groove is filled with sweet gel.

[0009] Preferably, an airflow guiding fan is installed at the front end of the trap housing, and the airflow guiding fan adopts an inward air intake design.

[0010] Preferably, the interior of the storage box is coated with a silver ion antibacterial coating.

[0011] The technical effects and advantages of this utility model are as follows:

[0012] In this invention, when workers need to pull out the storage box and clean the mosquito corpses inside, they pull the push-pull plate upwards to pull the limiting rod out of the limiting hole, thus releasing the storage box from its limit. The storage box can then be fully pulled out for further operations. After cleaning, the storage box is pushed back, and the push-pull plate is pulled up to align the limiting rod with the limiting hole. Pushing the push-pull plate again inserts the limiting rod back into the limiting hole, thus quickly fixing the storage box in place. This convenient fixing design ensures the storage box is securely fixed inside the trap shell during use, effectively preventing the trap shell from tipping over and causing the storage box to slip out. This avoids mosquito corpses falling to the outside and causing secondary pollution, effectively improving practicality. Attached Figure Description

[0013] The disclosure of this utility model is illustrated with reference to the accompanying drawings. It should be understood that the drawings are for illustrative purposes only and are not intended to limit the scope of protection of this utility model. In the drawings, the same reference numerals are used to refer to the same parts:

[0014] Figure 1 This is a schematic diagram of the main structure of the mosquito trap of this utility model;

[0015] Figure 2 This is a schematic diagram of the mosquito trapping component of this utility model;

[0016] Figure 3 This is a bottom view of the trap shell of this utility model;

[0017] Figure 4 This is a schematic diagram of the main structure of the storage box of this utility model.

[0018] Illustration: 1. Trapper housing; 2. Electric rotating top cover; 3. Fixing ring; 4. Mosquito trapping assembly; 5. Placement slot; 6. Storage box; 7. Fixing plate; 8. Sliding plate; 9. Limiting rod; 10. Connecting plate; 11. Limiting hole; 12. Elastic spring; 13. Bionic nectar gland slot; 14. Airflow guiding fan. Detailed Implementation

[0019] It is readily understood that, based on the technical solution of this utility model, those skilled in the art can propose various interchangeable structural methods and implementation methods without changing the essential spirit of this utility model. Therefore, the following specific embodiments and accompanying drawings are merely exemplary descriptions of the technical solution of this utility model, and should not be regarded as the entirety of this utility model or as a limitation or restriction on the technical solution of this utility model.

[0020] Reference Figures 1-4 As shown, this utility model provides a technical solution: an indoor mosquito trap with a biomimetic pitcher plant structure, including a trap shell 1; the top of the trap shell 1 is rotatably connected to an electrically rotating top cover 2; a fixing ring 3 is fixedly connected inside the trap shell 1; a mosquito trapping component 4 is installed at the bottom of the fixing ring 3; a placement groove 5 is opened at the front end of the trap shell 1; a storage box 6 is slidably connected inside the placement groove 5; a fixing plate 7 is fixedly connected to the front end of the storage box 6; a limit rod 9 is slidably connected inside the fixing plate 7; a push-pull plate 8 is fixedly connected to the top end of the limit rod 9; a connecting plate 10 is fixedly connected to the front end of the trap shell 1; a limit hole 11 is opened on the surface of the connecting plate 10; the interior of the limit hole 11 is slidably connected to the limit rod 9; when the worker needs to remove the mosquito trap, the device can be installed in the trap shell 1. When pulling out the storage box 6 and cleaning out the mosquito carcasses inside, pull the push-pull plate 8 upward to pull the limiting rod 9 out of the limiting hole 11, thus releasing the storage box 6 from its limit. Then, the storage box 6 can be fully pulled out for further operations. After cleaning, push the storage box 6 back in and pull up the push-pull plate 8 to align the limiting rod 9 with the limiting hole 11. Push the push-pull plate 8 again to insert the limiting rod 9 back into the limiting hole 11, thus quickly fixing the storage box 6. This convenient fixing feature ensures that the storage box 6 is securely fixed inside the trap shell 1 during use, effectively preventing the trap shell 1 from tipping over and causing the storage box 6 to slip out. This avoids mosquito carcasses falling to the outside and causing secondary pollution, effectively improving practicality.

[0021] Reference Figure 4 As shown in this embodiment: a spring spring 12 is sleeved on the surface of the limiting rod 9. The top and bottom ends of the spring spring 12 are fixedly connected to the fixing plate 7 and the push-pull plate 8, respectively. With the setting of the spring spring 12, when it is necessary to fix the position of the storage box 6, the limiting rod 9 is aligned with the limiting hole 11. At this time, the elastic force stored in the spring spring 12 is released, which drives the limiting rod 9 to be quickly inserted into the limiting hole 11, so as to achieve quick fixation after cleaning the inside of the storage box 6.

[0022] Reference Figure 3 and Figure 4As shown in this embodiment, the inner diameter of the limiting hole 11 is designed to match the size of the limiting rod 9. By matching the size of the limiting hole 11 with that of the limiting rod 9, displacement or shaking of the storage box 6 during the process of fixing it inside the trap shell 1 can be effectively prevented, thereby effectively ensuring the stability of the storage box 6 during the fixing process.

[0023] Reference Figure 1 As shown in this embodiment: a nectar gland bionic groove 13 is installed at the top of the trap shell 1. The inside of the nectar gland bionic groove 13 is filled with sweet gel. By filling the inside of the nectar gland bionic groove 13 with sweet gel, the substance secreted by the pitcher plant can be effectively imitated, thereby significantly improving the device's ability to attract mosquitoes and effectively enhancing the mosquito trapping effect.

[0024] Reference Figure 3 As shown in this embodiment: an airflow guiding fan 14 is installed at the front end of the trap shell 1. The airflow guiding fan 14 adopts an inward air intake design. By adopting an inward air intake design, the airflow guiding fan 14 can effectively avoid the influence of external wind on the odor inside the device and ensure the stability of the airflow inside the device. At the same time, the inward air intake design can also make the air entering the device more concentrated, thereby increasing the probability of mosquitoes being sucked into the device.

[0025] Reference Figure 4 As shown in this embodiment, the interior of the storage box 6 is coated with a silver ion antibacterial coating. By applying the silver ion antibacterial coating to the interior of the storage box 6, bacteria can be effectively prevented from growing when storing mosquito corpses, the generation of odors can be reduced, and the interior of the device can be kept clean and hygienic. This design not only improves the practicality of the device, but also increases its hygiene performance, allowing users to enjoy a fresher and healthier environment during use.

[0026] Working principle: When staff need to pull out the storage box 6 and clean out the dead mosquitoes inside, they pull the push-pull plate 8 upwards to disengage the limiting rod 9 from the limiting hole 11, releasing the storage box 6 from its limit. The storage box 6 can then be fully pulled out for further operations. After cleaning, the storage box 6 is pushed back, and the push-pull plate 8 is pulled up to align the limiting rod 9 with the limiting hole 11. Pushing the push-pull plate 8 then pushes the limiting rod 9 back into the limiting hole 11, thus quickly fixing the storage box 6. This convenient feature allows for easy fixing of the storage box 6. During use, the trap housing 1 securely fixes the storage box 6 inside, effectively preventing the storage box 6 from slipping out if the trap housing 1 tilts, thus avoiding secondary pollution caused by mosquito carcasses falling to the outside and improving practicality. Through the spring spring 12, when the position of the storage box 6 needs to be fixed, the limiting rod 9 is aligned with the limiting hole 11. The spring force stored in the spring spring 12 is released, causing the limiting rod 9 to quickly insert into the limiting hole 11, allowing the storage box 6 to be cleaned after use. The quick fixation, achieved through the matching size of the limiting hole 11 and the limiting rod 9, effectively prevents displacement or shaking of the storage box 6 during the fixation process inside the trap shell 1, thus ensuring the stability of the storage box 6 during fixation. By filling the inside of the nectar gland bionic groove 13 with sweet gel, it effectively mimics the substances secreted by pitcher plants, significantly enhancing the device's ability to attract mosquitoes and improving the mosquito trapping effect. The airflow guide fan 14 with an internal air intake design effectively avoids the influence of external wind on the internal odor of the device, ensuring the stability of the internal airflow. At the same time, the internal air intake design also makes the air entering the device more concentrated, thereby increasing the probability of mosquitoes being sucked into the device. By applying a silver ion antibacterial coating to the inside of the storage box 6, it can effectively prevent bacterial growth and reduce odor when storing mosquito corpses, keeping the inside of the device clean and hygienic. This design not only improves the practicality of the device but also increases its hygiene performance, allowing users to enjoy a fresher and healthier environment during use.

[0027] The technical scope of this utility model is not limited to the content described above. Those skilled in the art can make various modifications and variations to the above embodiments without departing from the technical concept of this utility model, and all such modifications and variations should fall within the protection scope of this utility model.

Claims

1. An indoor mosquito trap with a biomimetic pitcher plant structure, characterized in that, The device includes a trap housing (1): the top of the trap housing (1) is rotatably connected to an electric rotating top cover (2), the inside of the trap housing (1) is fixedly connected to a fixing ring (3), the bottom of the fixing ring (3) is equipped with a mosquito trapping component (4), the front end of the trap housing (1) is provided with a placement groove (5), the inside of the placement groove (5) is slidably connected to a storage box (6), the front end of the storage box (6) is fixedly connected to a fixing plate (7), the inside of the fixing plate (7) is slidably connected to a limiting rod (9), the top of the limiting rod (9) is fixedly connected to a push-pull plate (8), the front end of the trap housing (1) is fixedly connected to a connecting plate (10), the surface of the connecting plate (10) is provided with a limiting hole (11), the inside of the limiting hole (11) is slidably connected to the limiting rod (9).

2. The indoor mosquito trap with a biomimetic pitcher plant structure according to claim 1, characterized in that: The surface of the limiting rod (9) is fitted with a spring spring (12), and the top and bottom ends of the spring spring (12) are fixedly connected to the fixing plate (7) and the push-pull plate (8) respectively.

3. The indoor mosquito trap with a biomimetic pitcher plant structure according to claim 1, characterized in that: The inner diameter of the limiting hole (11) is designed to match the size of the limiting rod (9).

4. The indoor mosquito trap with a biomimetic pitcher plant structure according to claim 1, characterized in that: The top of the trap shell (1) is equipped with a honey gland bionic groove (13), and the inside of the honey gland bionic groove (13) is filled with sweet gel.

5. The indoor mosquito trap with a biomimetic pitcher plant structure according to claim 1, characterized in that: The front end of the trap housing (1) is equipped with an airflow guiding fan (14), which adopts an inward air intake design.

6. The indoor mosquito trap with a biomimetic pitcher plant structure according to claim 1, characterized in that: The interior of the storage box (6) is coated with a silver ion antibacterial coating.

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