Active induction automatic alarm remote automatic killing device
By employing composite baits and multiple sensors in the termite control device, combined with solar power and a dual extermination system, the problems of low termite control efficiency, limited coverage, and insufficient battery life in existing technologies have been solved, achieving efficient and precise termite control and environmentally friendly long-term stable operation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUNAN HUAHE CONSTR ENG MANAGEMENT CO LTD
- Filing Date
- 2025-08-25
- Publication Date
- 2026-07-14
AI Technical Summary
Existing termite control technologies suffer from problems such as low efficiency, high pollution, limited coverage, difficulty in real-time monitoring, insufficient endurance, limited functionality, and vulnerability to environmental damage, making it particularly difficult to achieve precise control in complex outdoor environments.
Employing a composite bait and multi-sensor synergy, combined with a dual extermination system, powered by solar energy, and integrating solenoid valves and miniature water pumps, it achieves precise agent delivery and efficient extermination. Combined with infrared and pressure sensors for real-time monitoring, it supports wireless data transmission and processing. Its structural design facilitates maintenance and expansion, and it is adaptable to complex outdoor environments.
It achieves efficient and precise termite control, reduces termite spread and damage, minimizes environmental impact, supports long-term stable operation, reduces management costs, and is suitable for complex outdoor scenarios.
Smart Images

Figure CN224482736U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of termite extermination technology, and in particular to an active induction automatic alarm remote automatic extermination device. Background Technology
[0002] Currently, termite control still relies mainly on traditional methods, which suffer from low efficiency, high pollution, and limited coverage. Traditional chemical control relies on large-scale spraying of pesticides, which not only easily causes soil and water pollution but may also harm other organisms. Moreover, the pesticides have a short effective period and require frequent reapplication. Physical control methods, such as manually digging up nests and setting up bait boxes, rely on manual inspections, making it difficult to monitor termite activity in real time. Termites often spread and become infested due to delayed detection, especially in complex environments such as forests, gardens, reservoirs, dams, and ancient buildings, where manual operation is difficult and can easily damage the environment. Existing automatic baiting devices are multifunctional but limited in scope, either only able to actively attract termites but not automatically kill them, or lacking remote alarm mechanisms, making it difficult to achieve precise control. At the same time, outdoor devices are often limited by power supply, with insufficient battery life, making it difficult to operate stably for long periods in areas without mains power, resulting in a significant reduction in control effectiveness. Therefore, there is a need for an intelligent device that integrates active attraction, real-time monitoring, automatic extermination, unattended operation, and green energy supply to solve the pain points of traditional control methods. Utility Model Content
[0003] The purpose of this utility model is to solve at least one of the technical problems existing in the prior art, and to provide an active induction automatic alarm remote automatic extermination device. First, it achieves efficient and precise prevention and control by combining composite bait with multiple sensors and a dual extermination system, reducing termite spread and damage. Second, it is environmentally friendly and safe, with precise drug delivery and directional physical extermination, resulting in minimal environmental impact. Third, it is solar-powered and durable, adapting to complex outdoor scenarios without mains power. Fourth, its structural design facilitates maintenance, supports network expansion, and reduces management costs. Fifth, it integrates multiple modules to form an automated closed loop, suitable for hidden areas, filling the blind spots of traditional prevention and control, reducing manual duty, and addressing the challenges of patrolling in harsh terrain.
[0004] This utility model also provides a remote automatic extermination device with the above-mentioned active inducement automatic alarm, a base, a metal conductive ring fixedly connected to the bottom near the outside of the base, a metal porous box tightly attached to the outer surface of the metal conductive ring, a solar panel fixedly connected to the upper end of the base via a connecting wire to provide power, a battery fixedly connected to the inside of the base near the top, a circuit board fixedly connected to the inside of the base near the bottom, a wedge block fixedly connected to the bottom center of the base, a connecting plate inserted into the outer surface of the wedge block, a spraying sleeve fixedly connected to the bottom of the connecting plate, a bionic inner liner threaded to the outer surface of the spraying sleeve, and a spraying mechanism provided inside the spraying sleeve;
[0005] The spraying mechanism includes:
[0006] The solenoid valve is located at the center of the bottom of the spraying sleeve.
[0007] A miniature water pump is located at the bottom of the spraying sleeve and close to the inner wall of the spraying sleeve.
[0008] According to the aforementioned active-induced automatic alarm remote automatic extermination device, a sealed corrugated pipe is fixedly connected to the outer surface of the end of the connecting line away from the base, and the top of the sealed corrugated pipe is fixedly connected to the bottom of the solar panel.
[0009] By adopting the above technical solution, the sealed corrugated pipe is sleeved outside the connecting line, which can effectively isolate rainwater, dust and other external impurities, prevent the connecting line from being damaged by moisture, corrosion and other factors, greatly improve the stability and reliability of power transmission between the solar panel and the base, ensure the long-term stable operation of the device in complex outdoor environments, and guarantee the normal operation of the energy supply system.
[0010] According to the aforementioned active-induced automatic alarm remote automatic extermination device, the upper end of the circuit board is respectively provided with a first relay, a second relay, a wireless data transmission module, and a data processing module.
[0011] By adopting the above technical solution, the wireless data transmission module undertakes the important task of transmitting the termite intrusion information collected by the sensor to the control center at high speed and stably. The data processing module analyzes and identifies the sensor signals to confirm the termite intrusion situation, providing accurate basis for subsequent alarm and extermination operations. It is the core component for realizing intelligent linkage.
[0012] According to the aforementioned active-induced automatic alarm remote automatic extermination device, a heating device is fixedly connected to the bottom inner wall of the metal porous box, and the heating device is located directly below the bionic inner liner.
[0013] By adopting the above technical solution, in the active induction stage, it releases a suitable temperature to simulate the warm environment of a termite nest. Combined with the composite bait in the biomimetic inner liner, it enhances the attraction to termites from both temperature and food aspects, thereby improving the efficiency of active induction. In the high-temperature extermination stage, it can quickly raise the temperature to above ℃, using the high temperature to denature the termite proteins.
[0014] According to the aforementioned active-induced automatic alarm remote automatic extermination device, the four corner points of the solar panel are vertically fixedly connected to connecting rods, and the bottom of the four connecting rods are fixedly connected to annular sliders, the outer surface of the annular sliders sliding on the inner wall of the annular slide rail.
[0015] By adopting the above technical solution, users can manually and flexibly adjust the angle of the solar panel according to the lighting conditions at different times and angles, ensuring that it is always in the best position for receiving sunlight, and maximizing the collection and conversion efficiency of solar energy.
[0016] According to the aforementioned active-induced automatic alarm remote automatic extermination device, the upper end of the micro water pump is fixedly connected to a first connecting pipe, and the end of the first connecting pipe away from the micro water pump is threadedly connected to a medicine tank.
[0017] By adopting the above technical solution, after the micro water pump is started, the highly efficient and environmentally friendly termite pesticide in the medicine tank is stably drawn into the micro water pump through the first connecting pipe, which prepares for the subsequent precise spraying of the pesticide into the bionic inner liner through the second connecting pipe.
[0018] According to the aforementioned active-induced automatic alarm remote automatic extermination device, the upper end of the micro water pump is fixedly connected to the solenoid valve through a second connecting pipe, and a nozzle is fixedly connected to the bottom of the solenoid valve, with the lower end of the nozzle extending into the interior of the bionic inner liner.
[0019] By adopting the above technical solution, the solenoid valve controls the flow rate of the agent, and the nozzle sprays the agent in the form of atomization precisely onto the termite gathering area inside the bionic inner liner, ensuring that the agent can evenly cover the termites and bait, and quickly exert its effect.
[0020] According to the aforementioned active-induced automatic alarm remote automatic extermination device, the bionic inner liner is equipped with an infrared sensor and a pressure sensor.
[0021] By adopting the above technical solution, the infrared sensor monitors the infrared radiation generated by termite activity in real time, and the pressure sensor keenly captures the pressure changes caused by the aggregation of termite colonies. The two work together with the micro switch to accurately sense the termite invasion and provide accurate signals to the data processing module on the circuit board.
[0022] Additional aspects and advantages of this invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. Attached Figure Description
[0023] The present invention will be further described below with reference to the accompanying drawings and embodiments;
[0024] Figure 1 This is an overall structural diagram of the active-induced automatic alarm remote automatic extermination device of this utility model;
[0025] Figure 2 This is a structural diagram of the solar-powered angle structure of the active-induced automatic alarm remote automatic extermination device of this utility model;
[0026] Figure 3 This is an internal structural diagram of the active-induced automatic alarm remote automatic extermination device of this utility model;
[0027] Figure 4This is a schematic diagram of the spraying structure of the active-induced automatic alarm remote automatic pest control device of this utility model.
[0028] Legend:
[0029] 1. Base; 2. Perforated metal box; 3. Heating device; 4. Connecting wire; 5. Circular slide rail; 6. Circular slider; 7. Connecting rod; 8. Solar panel; 9. Sealed bellows; 10. Battery; 11. Circuit board; 12. First relay; 13. Second relay; 14. Wireless data transmission module; 15. Data processing module; 16. Wedge block; 17. Connecting plate; 18. Bionic inner liner; 19. Spraying sleeve; 20. Medicine tank; 21. First connecting pipe; 22. Miniature water pump; 23. Second connecting pipe; 24. Solenoid valve; 25. Nozzle; 26. Metal conductive ring. Detailed Implementation
[0030] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.
[0031] Reference Figure 1-4 This utility model embodiment of the active inducement automatic alarm remote automatic extermination device includes a base 1, a metal conductive ring 26 fixedly connected to the bottom of the base 1 near the outer side, a metal porous box 2 tightly attached to the outer surface of the metal conductive ring 26, a solar panel 8 fixedly connected to the upper end of the base 1 via a connecting wire 4, a battery 10 fixedly connected to the inside of the base 1 near the top, a circuit board 11 fixedly connected to the inside of the base 1 near the bottom, a wedge block 16 fixedly connected to the bottom center of the base 1, a connecting plate 17 inserted into the outer surface of the wedge block 16, a spraying sleeve 19 fixedly connected to the bottom of the connecting plate 17, a bionic inner liner 18 threadedly connected to the outer surface of the spraying sleeve 19, and a spraying mechanism provided inside the spraying sleeve 19.
[0032] A sealing bellows 9 is fixedly connected to the outer surface of the end of the connecting line 4 away from the base 1. The top of the sealing bellows 9 is fixedly connected to the bottom of the solar panel 8. The upper end of the circuit board 11 is respectively provided with a first relay 12, a second relay 13, a wireless data transmission module 14 and a data processing module 15. A heating device 3 is fixedly connected to the bottom inner wall of the metal porous box 2. The heating device 3 is located directly below the bionic inner liner 18. Connecting rods 7 are vertically fixedly connected to the four corners of the solar panel 8. Annular sliders 6 are fixedly connected to the bottom of the four connecting rods 7. The outer surface of the annular sliders 6 slides on the inner wall of the annular slide rail 5.
[0033] The spraying equipment includes:
[0034] Solenoid valve 24 is located at the bottom center of spray sleeve 19.
[0035] The miniature water pump 22 is located at the bottom of the spray sleeve 19 and close to the inner wall of the spray sleeve 19.
[0036] The upper end of the micro water pump 22 is fixedly connected to the first connecting pipe 21. The end of the first connecting pipe 21 away from the micro water pump 22 is threadedly connected to the medicine tank 20. The upper end of the micro water pump 22 is fixedly connected to the solenoid valve 24 through the second connecting pipe 23. The bottom of the solenoid valve 24 is fixedly connected to the nozzle 25. The lower end of the nozzle 25 extends into the interior of the bionic inner liner 18. An infrared sensor and a pressure sensor are installed inside the bionic inner liner 18.
[0037] Working principle: This device achieves precise control of termites through a closed-loop design that integrates active induction and enhancement, multi-dimensional perception, intelligent linkage, multi-eradication, and self-sufficiency in energy, as well as reducing manual operation and addressing the challenges of harsh terrain for inspection and patrol.
[0038] The core active induction component of the device is the bionic inner liner 18, which is equipped with a composite bait system. It uses traditional baits such as dried pine wood, sugarcane bagasse, and cellulose as the base carriers, and evenly mixes them with specially made termite pheromones. The pheromones can simulate the foraging signals of termite colonies and form an odor field with a wider diffusion range in the air, which can attract termite clusters from a greater distance to forage. At the same time, the heating device 3 at the bottom of the porous metal box 2 can release a suitable temperature during the active induction stage. Combined with the simulated environment of the bionic inner liner 18, it can enhance the dual attraction of the termites' sense of smell and the environment, thereby improving the efficiency of active induction.
[0039] The sensing system within the bionic inner liner 18 employs a triple triggering mechanism. For signal acquisition, microswitches, pressure sensors, and infrared sensors are deployed around the bait. When termites feed, touching the bait triggers the microswitches, causing localized pressure changes due to the gathering of termites, which are captured by the pressure sensors. Simultaneously, the infrared sensors monitor the infrared radiation generated by termite activity in real time. During signal processing, the weak electrical signals output by the sensors are first amplified by an amplification circuit and then filtered to remove environmental electromagnetic interference, forming a stable trigger signal. In the remote alarm phase, the processed signal is transmitted to the data processing module 15 on the circuit board 11. After confirming termite intrusion, the wireless data transmission module 14 sends the alarm information to the control center in a high-speed and stable manner, ensuring no delay in information delivery. Upon receiving the alarm signal, the control center immediately initiates the extermination process according to preset instructions. This dual extermination module achieves efficient control, and the pesticide delivery system... In this process, a control signal triggers the linkage between the micro water pump 22 and the solenoid valve 24. The highly efficient and environmentally friendly termite pesticide in the pesticide tank 20 is transported through precision pipelines such as the first connecting pipe 21 and the second connecting pipe 23, and is precisely sprayed by the nozzle 25 onto the termite gathering area inside the bionic inner liner 18. The pesticide acts directly on the insects and bait, achieving rapid extermination and forming a continuous control barrier. The physical extermination device includes an electric shock device and a high-temperature device with the heating device 3 as its core. The electric shock device receives the control signal at the electrode at the termite gathering point, and the base 1 transmits the current to the metal porous box 2 through the metal conductive ring 26, so that the electrodes on the metal porous box 2 are instantly supplied with high voltage. The current penetrates the termite body wall, instantly killing adult and larval insects. The high-temperature device relies on the high-performance heating element of the heating device 3 to raise the local temperature of the bionic inner liner 18 to above 60°C within 3-5 seconds. The high-temperature protein denaturation principle is used to completely kill the termites and destroy the activity of the insect eggs.
[0040] For outdoor scenarios with ample sunlight, the solar panel 8 on the top of the device can be adjusted in angle by manually adjusting the position of the ring slider 6 on the ring slide rail 5 to adapt to different directions of sunlight. The solar panel 8 is connected to the base 1 via a connecting line 4, and the sealed corrugated pipe 9 on the outer surface of the connecting line 4 provides protection. The solar panel 8 efficiently converts solar energy into electrical energy, which is stored in the battery 10 inside the base 1. This provides continuous and stable power support for all electrical components such as sensors, wireless modules, micro water pumps 22, and heating devices 3, ensuring that the device can operate autonomously for a long time in an environment without an external power source.
[0041] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.
Claims
1. An active-guided automatic alarm remote automatic extermination device, characterized in that, include: A base (1) is fixedly connected to a metal conductive ring (26) near the bottom of the base (1). A metal porous box (2) is tightly attached to the outer surface of the metal conductive ring (26). A solar panel (8) is fixedly connected to the upper end of the base (1) via a connecting line (4). A battery (10) is fixedly connected to the inside of the base (1) near the top. A circuit board (11) is fixedly connected to the inside of the base (1) near the bottom. A wedge block (16) is fixedly connected to the center of the bottom of the base (1). A connecting plate (17) is inserted into the outer surface of the wedge block (16). A spraying sleeve (19) is fixedly connected to the bottom of the connecting plate (17). A bionic inner liner (18) is threaded onto the outer surface of the spraying sleeve (19). A spraying mechanism is provided inside the spraying sleeve (19). The spraying mechanism includes: Solenoid valve (24) is located at the center of the bottom of the spray sleeve (19); A miniature water pump (22) is located at the bottom of the spray sleeve (19) and close to the inner wall of the spray sleeve (19).
2. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, A sealing bellows (9) is fixedly connected to the outer surface of the end of the connecting line (4) away from the base (1), and the top of the sealing bellows (9) is fixedly connected to the bottom of the solar panel (8).
3. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, The upper end of the circuit board (11) is respectively provided with a first relay (12), a second relay (13), a wireless data transmission module (14) and a data processing module (15).
4. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, A heating device (3) is fixedly connected to the bottom inner wall of the metal porous box (2), and the heating device (3) is located directly below the bionic inner liner (18).
5. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, The solar panel (8) is vertically fixed to four corner points with connecting rods (7), and the bottom of the four connecting rods (7) is fixedly connected to annular sliders (6). The outer surface of the annular sliders (6) slides on the inner wall of the annular slide rail (5).
6. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, The upper end of the micro water pump (22) is fixedly connected to a first connecting pipe (21), and the end of the first connecting pipe (21) away from the micro water pump (22) is threadedly connected to a medicine container (20).
7. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, The upper end of the micro water pump (22) is fixedly connected to the solenoid valve (24) through the second connecting pipe (23). The bottom of the solenoid valve (24) is fixedly connected to the nozzle (25), and the lower end of the nozzle (25) extends into the interior of the bionic inner liner (18).
8. The active-induced automatic alarm remote automatic extermination device according to claim 1, characterized in that, The bionic inner liner (18) is equipped with an infrared sensor and a pressure sensor.