Intelligent high-altitude weather forecasting lamp device
By designing an intelligent high-altitude monitoring light device, insects are captured and monitored in real time by utilizing their phototaxis. Combined with solar power, this solves the problem of untimely insect sample collection and achieves efficient and low-cost pest and disease monitoring.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANGHAI YIYA INTERNET OF THINGS TECH CO LTD
- Filing Date
- 2025-06-16
- Publication Date
- 2026-06-19
AI Technical Summary
Existing high-altitude monitoring lamps lack real-time dynamic monitoring and intelligent identification functions, resulting in untimely insect sample collection, which affects the accuracy and timeliness of pest and disease monitoring, and manual inspection is costly.
Design an intelligent high-altitude monitoring light device, comprising an attraction component, an electric grid, a camera component, and a power storage component. It uses the phototaxis of insects to kill them, monitors and transmits data in real time through a camera, and combines solar power to achieve automatic cleaning and remote monitoring, reducing human intervention.
It enables real-time remote monitoring and automatic cleaning of insect samples, improving the timeliness and accuracy of pest and disease monitoring, reducing labor costs, extending equipment battery life, and adapting to complex environments.
Smart Images

Figure CN224368844U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of high-altitude monitoring lights, specifically an intelligent high-altitude monitoring light device. Background Technology
[0002] High-altitude monitoring and forecasting lamp equipment utilizes the phototaxis of insects. By turning on a strong light at night, it attracts insects flying at high altitudes. Then, using an automatic control system and insect collection device, the attracted insects are collected, classified, and counted, thereby providing data support for entomological research, pest and disease monitoring and early warning.
[0003] In existing technologies, insects are typically killed using an electric grid after being trapped by light sources. The killed insects fall directly into a collection tube below under gravity. Due to the lack of real-time dynamic monitoring and intelligent identification functions, inspectors must regularly visit the equipment site, manually open the collection tube, and meticulously identify the quantity and morphological characteristics of the insect samples in the tube through traditional methods such as visual observation or simple image acquisition to determine the insect species and population dynamics in the near future. This work mode, which relies on regular manual inspections, not only suffers from poor timeliness and high labor costs, but also easily leads to untimely sample collection when encountering severe weather or inconvenient transportation, affecting the accuracy and timeliness of pest and disease monitoring and early warning. Therefore, we propose an intelligent high-altitude monitoring light device. Utility Model Content
[0004] The purpose of this utility model is to provide an intelligent high-altitude monitoring light device to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: an intelligent high-altitude monitoring light device, comprising a housing, a conical cylinder fixedly connected to the top of the housing, a collection groove opened inside the conical cylinder, an induction component fixedly connected inside the collection groove, multiple electric grid plates fixedly connected to the top of the induction component, a collection component slidably connected inside the housing, a power storage component fixedly connected to the rear side of the housing, a camera component fixedly connected inside the housing, a cylinder fixedly connected inside the housing, a push rod fixedly connected to the output end of the cylinder, a sliding column fixedly connected to the outside of the push rod, two limiting columns fixedly connected inside the housing, a scraper fixedly connected to the bottom of the sliding column, a brush installed at the bottom of the sliding column, two limiting rods fixedly connected inside the housing, and a detection plate fixedly connected to the outside of the two limiting rods.
[0006] The box has four fixed support columns at the bottom corners, and two rotating doors are rotatably connected inside the box. Each rotating door has a pull handle fixedly connected to its exterior.
[0007] The attraction component has a base mounted on top, and an attraction light is mounted on top of the base.
[0008] The collection component has two fixed external limit blocks, and a rotating handle is rotatably connected to the side of the two limit blocks that are close to each other.
[0009] The energy storage component has two connecting rods fixedly connected to its exterior. A support rod is fixedly connected to the top of each connecting rod. An installation sleeve is installed on the outside of the connecting rod. A solar panel is installed on the top of each of the two installation sleeves. A connecting wire is installed on the outside of the solar panel. An energy storage box is fixedly connected to the other side of the connecting wire.
[0010] The solar panel is fixedly connected to the top of the support rod at the bottom, and the energy storage box is fixedly connected to the outside of the box body.
[0011] The camera assembly is externally fixed to a connecting column, which is rotatably connected to a rotating rod inside the connecting column. A camera is externally fixed to the rotating rod, and a second connecting line is externally fixed to the connecting column. A transmission controller is externally fixed to the other side of the second connecting line, and the transmission controller is externally fixed to the inside of the housing.
[0012] This utility model has at least the following beneficial effects:
[0013] In use, this invention attracts high-altitude insects using a phototactic lamp, which is then captured by an electric grid. The insect carcasses fall into a collection trough onto a detection tray. A camera captures images of the insect carcasses on the tray, which are then transmitted to the user via a transmission controller. This enables real-time remote monitoring of insect populations, replacing the inefficient manual periodic inspections. It improves the timeliness and accuracy of pest monitoring, reduces labor costs, and allows for different time-period photography. When different time periods require shooting, a cylinder is activated to drive a push rod and sliding column, causing a scraper and brush to clean the detection tray and scrape the insect carcasses into the collection tray, ensuring its reusability and continuous monitoring of insect population changes. A solar panel receives and stores solar energy in a storage box, providing green energy for the equipment's operation, effectively extending its runtime, reducing reliance on traditional electricity, lowering operating costs, and enhancing its continuous operation in complex field environments, thus ensuring the stable operation of high-altitude monitoring. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the structure of this utility model;
[0015] Figure 2 This is a schematic diagram of the detection disc structure of this utility model;
[0016] Figure 3 This is a schematic diagram of the conical cylinder structure of this utility model;
[0017] Figure 4 This is a schematic diagram of the internal structure of this utility model;
[0018] Figure 5 This is a schematic diagram of the energy storage component structure of this utility model;
[0019] Figure 6 This is a schematic diagram of the structure of the collection component of this utility model;
[0020] Figure 7 This is a schematic diagram of the imaging component structure of this utility model;
[0021] In the diagram: 1. Box body; 101. Support column; 102. Rotating door; 103. Pull handle; 2. Conical cylinder; 201. Collection trough; 202. Inducing component; 203. Base; 204. Inducing light; 3. Grid plate; 4. Collection component; 401. Limiting block; 402. Rotating handle; 5. Energy storage component; 501. Connecting rod; 502. Supporting rod; 503. Mounting sleeve; 504. Solar panel; 505. Connecting wire one; 506. Energy storage box; 6. Camera component; 601. Connecting column; 602. Rotating rod; 603. Camera; 604. Connecting wire two; 605. Transmission controller; 7. Cylinder; 701. Push rod; 702. Sliding column; 703. Limiting column; 704. Scraper; 705. Brush; 8. Limiting rod; 801. Detection plate. Detailed Implementation
[0022] 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 protection scope of the present utility model.
[0023] Example 1
[0024] Please see Figures 1 to 7This utility model provides a technical solution: an intelligent high-altitude monitoring light device, including a housing 1, a conical cylinder 2 fixedly connected to the top of the housing 1, a collection groove 201 inside the conical cylinder 2, an induction component 202 fixedly connected inside the collection groove 201, multiple electric grid plates 3 fixedly connected to the top of the induction component 202, a collection component 4 slidably connected inside the housing 1, a power storage component 5 fixedly connected to the rear side of the housing 1, a shooting component 6 fixedly connected inside the housing 1, a cylinder 7 fixedly connected inside the housing 1, a push rod 701 fixedly connected to the output end of the cylinder 7, a sliding column 702 fixedly connected to the outside of the push rod 701, two limiting columns 703 fixedly connected inside the housing 1, a scraper 704 fixedly connected to the bottom of the sliding column 702, and a brush 70 installed at the bottom of the sliding column 702. 5. Two limiting rods 8 are fixedly connected inside the box 1, and a detection plate 801 is fixedly connected to the outside of the two limiting rods 8. When insects approach the attraction lamp 204, they will come into contact with the electric grid plate 3. The electric grid plate 3 will kill the insects by electric shock. After being killed, the insects fall into the collection tank 201 and onto the top of the detection plate 801. When the detection plate 801 needs to be cleaned, the cylinder 7 inside the box 1 is activated. The cylinder 7 pushes the sliding column 702 through the push rod 701. The sliding column 702 slides downward along the outside of the limiting column 703. At this time, the scraper 704 fixed at the bottom of the sliding column 702 scrapes off the insect corpses on the top of the detection plate 801 and pushes them away from the detection plate 801. Then, the brush 705 brushes the surface of the detection plate 801 to further clean up the remaining insect debris and ensure that the detection plate 801 is clean.
[0025] Support columns 101 are fixedly connected to the four corners of the bottom of the box 1. There are two rotating doors 102 inside the box 1. Pull handles 103 are fixedly connected to the outside of the rotating doors 102. The pull handles 103 are fixedly connected to the outside of the rotating doors 102 to provide a gripping point for the operator to open and close the rotating doors 102.
[0026] The attractant assembly 202 is topped with a base 203, and an attractant lamp 204 is mounted on top of the base 203. A power storage box 506 supplies power to the attractant lamp 204. When the attractant lamp 204 is turned on, it utilizes the phototaxis of insects to attract insects from high altitudes to the vicinity of the device.
[0027] The collection component 4 is externally fixedly connected to two limiting blocks 401, and a rotating handle 402 is rotatably connected to the side of the two limiting blocks 401 that are close to each other; the cleaned insect corpses fall into the collection component 4 for collection.
[0028] The energy storage component 5 is externally fixedly connected to two connecting rods 501. A support rod 502 is fixedly connected to the top of the connecting rods 501. An installation sleeve 503 is installed on the outside of the connecting rods 501. A solar panel 504 is installed on the top of the two installation sleeves 503. A connecting line 505 is installed on the outside of the solar panel 504. An energy storage box 506 is fixedly connected to the other side of the connecting line 505. The bottom of the solar panel 504 is fixedly connected to the top of the support rod 502. The energy storage box 506 is externally fixedly connected to the outside of the box body 1. During the day, it receives solar energy and converts it into electrical energy. The converted electrical energy is transmitted to the energy storage box 506 for storage through the connecting line 505. The electrical energy stored in the energy storage box 506 powers the equipment components such as the induction light 204, the shooting component 6, and the cylinder 7, reducing dependence on external power sources, extending the equipment's operating time, and ensuring continuous and stable operation of the equipment in various environments.
[0029] The imaging component 6 is externally fixedly connected to a connecting post 601, and internally rotatably connected to a rotating rod 602. A camera 603 is externally fixedly connected to the rotating rod 602, and a second connecting line 604 is externally fixedly connected to the connecting post 601. A transmission controller 605 is fixedly connected to the other side of the second connecting line 604, and the transmission controller 605 is externally fixedly connected inside the housing 1. The camera 603 in the imaging component 6 adjusts its shooting angle via the rotating rod 602 to capture images of insect carcasses on the top of the detection disc 801. The captured image data is transmitted to the transmission controller 605 via the second connecting line 604, and then sent by the transmission controller 605 to the user, enabling remote real-time monitoring of insect infestations.
[0030] The working principle of this utility model is as follows: When trapping insects in the air, it is only necessary to power the attraction lamp 204 through the power storage box 506, so that the attraction lamp 204 is turned on. Then, the attraction lamp 204 uses the phototaxis of insects to attract insects in the air. When the insects fall near the attraction lamp 204, they will come into contact with the outside of the electric grid plate 3, and then the electric grid plate 3 will kill the insects. The killed insects will fall down through the collection trough 201 to the top of the detection plate 801. In order to monitor the current insect situation, it is only necessary to use the shooting component 6 in conjunction with the connecting column 601 and the camera 603. The camera 603 takes pictures of the dead insects trapped on the top of the detection plate 801, and then transmits the pictures to the user through the connecting cable 604 in conjunction with the transmission controller 605.
[0031] Then, in order to perform shooting at different times, when it is necessary to clean the top of the detection plate 801, simply activate the cylinder 7 inside the housing 1, so that the cylinder 7, together with the push rod 701, pushes the sliding column 702, causing the sliding column 702 to slide outside the limit column 703. Then, the scraper 704 scrapes off the insect corpses on the top of the detection plate 801, and then the brush 705 brushes and cleans the top of the detection plate 801, causing the insect corpses on the top of the detection plate 801 to fall into the collection component 4 for collection. After the detection plate 801 is full of insect corpses again, the camera 603 takes pictures and transmits them.
[0032] Example 2
[0033] Please see Figures 1 to 2 In this second embodiment, the other structures remain unchanged. The difference from the first embodiment is that a solar panel 504 is installed on the top of the mounting sleeve 503, which allows the solar panel 504 to receive solar energy and store electrical energy in the storage box 506 through the connecting wire 505, thereby extending the operating time of the device.
[0034] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.
[0035] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. An intelligent high-altitude monitoring and reporting light device, comprising a housing (1), characterized in that: A conical cylinder (2) is fixedly connected to the top of the housing (1). A collection groove (201) is provided inside the conical cylinder (2). An induction component (202) is fixedly connected inside the collection groove (201). Multiple grid plates (3) are fixedly connected to the top of the induction component (202). A collection component (4) is slidably connected inside the housing (1). A power storage component (5) is fixedly connected to the rear side of the housing (1). A camera component (6) is fixedly connected inside the housing (1). There is a cylinder (7), and a push rod (701) is fixedly connected to the output end of the cylinder (7). A sliding column (702) is fixedly connected to the outside of the push rod (701). Two limiting columns (703) are fixedly connected inside the housing (1). A scraper (704) is fixedly connected to the bottom of the sliding column (702). A brush (705) is installed at the bottom of the sliding column (702). Two limiting rods (8) are fixedly connected inside the housing (1). A detection plate (801) is fixedly connected to the outside of the two limiting rods (8).
2. The intelligent high-altitude monitoring light device according to claim 1, characterized in that: The box (1) has four fixed support columns (101) at the bottom corners. The box (1) has two rotating doors (102) inside. The rotating doors (102) are fixedly connected to the outside of the doors (103).
3. The intelligent high-altitude monitoring light device according to claim 1, characterized in that: The lure assembly (202) is mounted on a base (203) on top, and the base (203) is mounted on a lure lamp (204) on top.
4. The intelligent high-altitude monitoring light device according to claim 1, characterized in that: The collecting component (4) is externally fixedly connected to two limiting blocks (401), and a rotating handle (402) is rotatably connected to the two limiting blocks (401) on the side closest to each other.
5. The intelligent high-altitude monitoring light device according to claim 1, characterized in that: The energy storage component (5) is externally fixedly connected to two connecting rods (501). A support rod (502) is fixedly connected to the top of the connecting rod (501). An installation sleeve (503) is installed on the outside of the connecting rod (501). A solar panel (504) is installed on the top of the two installation sleeves (503). A connecting wire (505) is installed on the outside of the solar panel (504). An energy storage box (506) is fixedly connected to the other side of the connecting wire (505).
6. The intelligent high-altitude monitoring light device according to claim 5, characterized in that: The bottom of the solar panel (504) is fixedly connected to the top of the support rod (502), and the external of the energy storage box (506) is fixedly connected to the outside of the box body (1).
7. The intelligent high-altitude monitoring light device according to claim 1, characterized in that: The shooting component (6) is externally fixedly connected to a connecting post (601), and a rotating rod (602) is rotatably connected inside the connecting post (601). A camera (603) is externally fixedly connected to the rotating rod (602). A second connecting line (604) is externally fixedly connected to the connecting post (601). A transmission controller (605) is fixedly connected to the other side of the second connecting line (604). The transmission controller (605) is externally fixedly connected inside the housing (1).