Energy-saving intelligent lighting device for scenic spots
By designing a landscape trapping unit and a rainwater reuse module, the problem of insect blockage and secondary pest infestation after mosquitoes die in energy-saving smart lighting devices used in scenic areas has been solved. This has enabled efficient mosquito trapping and rainwater recycling, improving the effectiveness and environmental friendliness of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SENKOO (SHANGHAI) BRAND PLANNING CO LTD
- Filing Date
- 2026-05-07
- Publication Date
- 2026-06-30
AI Technical Summary
In existing energy-saving smart lighting devices used in scenic areas, the dried bodies of dead mosquitoes can easily clog the mesh, obstructing airflow and reducing the efficiency of mosquito trapping. Furthermore, the accumulated insect carcasses are prone to mold and bacterial growth in humid environments, leading to secondary pest infestations.
An energy-saving smart lighting device for scenic areas was designed, comprising a landscape trapping unit and a rainwater reuse module. The landscape trapping unit achieves active capture of mosquitoes and automatic cleaning of dried insect bodies through an active air pump and gear mechanism. The rainwater reuse module achieves rainwater collection and purification through self-washing nozzles and filter frames.
It effectively prevents dried insects from clogging the mesh, ensures airflow, improves mosquito trapping efficiency, prevents secondary pest infestations, and reduces operation and maintenance costs and environmental pollution through rainwater recycling.
Smart Images

Figure CN122305435A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of smart lighting equipment technology, and in particular to an energy-saving smart lighting device for scenic areas. Background Technology
[0002] Traditional scenic area lighting has long relied on high-energy-consuming equipment such as metal halide lamps and high-pressure sodium lamps, which not only incurs high operation and maintenance costs but also contradicts the current industrial orientation of low-carbon and environmental protection. With the advancement of the "dual carbon" goal, energy-saving lighting equipment, with its ultra-high luminous efficiency and lifespan, has become the core path for the green transformation of scenic area lighting, significantly reducing energy consumption and carbon emissions while improving the night scene effect.
[0003] At the same time, the integration of new lighting technologies and intelligent management is giving scenic area lighting a new artistic and functional value. Among them, electroluminescence technology, with its flexible, thin and large-area uniform light emission characteristics, is particularly suitable for low glare scenarios such as landscape walkway light strips and building outlines. On this basis, scenic areas can not only further dynamically adjust energy consumption, but also realize proactive operation and maintenance such as pedestrian flow monitoring and fault early warning.
[0004] Existing energy-saving smart lighting devices in scenic areas use trap lights to catch mosquitoes. However, after the mosquitoes die, their dried bodies adhere to the mesh and inner wall of the insect-collecting net frame or bag. Over time, this can easily cause the mesh to become clogged, obstructing the airflow and reducing the efficiency of mosquito trapping. Furthermore, the accumulated insect carcasses are prone to becoming damp and moldy in humid environments, breeding bacteria and causing secondary pest infestations, thus affecting the effectiveness of the lighting devices in the scenic area. Summary of the Invention
[0005] This invention discloses an energy-saving smart lighting device for scenic areas, which aims to solve the technical problems in the background art where the dried bodies of dead mosquitoes easily cause mesh blockage, thereby obstructing the airflow channel, reducing the mosquito-trapping efficiency, and the long-term accumulation of insect corpses in humid environments are also prone to becoming damp and moldy, breeding bacteria, and causing secondary insect infestations.
[0006] This invention proposes an energy-saving smart lighting device for scenic areas, comprising:
[0007] A lighting pole with a lamp wick and a diffuser, the lamp wick being located inside the diffuser;
[0008] Two disassembly mesh panels are provided, both of which are mounted on a lighting pole, and the lighting pole has a shaking chamber.
[0009] Multiple fixed poles are provided, all of which are mounted on lighting poles. The multiple fixed poles are provided with the same upper lamp post, and the upper lamp post is provided with an installation cavity and an air inlet cavity.
[0010] A dustproof ring frame is installed on the upper lamp post, and a photovoltaic bracket is also installed on the upper lamp post, with multiple photovoltaic panels installed on the photovoltaic bracket;
[0011] The smart camera module is installed on the lamp post.
[0012] A landscape trapping unit is installed on an upper lamp post, a lighting lamp post, and multiple fixed poles. The landscape trapping unit includes a retractable bucket, an upper net bag, and a lower net bag, with the upper net bag located above the lower net bag.
[0013] A rainwater reuse module is installed on the upper lamp post. The rainwater reuse module includes multiple self-washing nozzles and a water ring.
[0014] In a preferred embodiment, the landscape trapping unit further includes:
[0015] A connecting compartment is located inside the air intake chamber, and an active air pump is installed on the connecting compartment;
[0016] Multiple airflow pipes are installed on the connecting chamber, and each of the multiple airflow pipes has an airflow nozzle at its output end. The multiple airflow nozzles are installed on the upper lamp post, and the smart camera is located between the multiple airflow nozzles.
[0017] In a preferred embodiment, the landscape trapping unit further includes:
[0018] A fixed ring frame is provided on multiple fixed uprights, and a trapping light body is provided on the fixed ring frame. The trapping light body is located below the smart camera structure.
[0019] Guide plate, the guide plate is set on the fixed ring frame;
[0020] The mosquito frame is mounted on a lighting pole, the retractable hopper is mounted on the mosquito frame, the guide plate is located above the retractable hopper, and the retractable hopper is also provided with multiple installation ports.
[0021] In a preferred embodiment, the landscape trapping unit further includes:
[0022] Multiple diversion hoppers are respectively set on multiple installation ports. One end of the upper net bag is set on the mosquito frame. Both the upper net bag and the lower net bag are located inside the shaking chamber.
[0023] Two fixed supports are provided, both of which are located inside the shaking chamber, and each of the two fixed supports is equipped with a mounting shaft.
[0024] In a preferred embodiment, the landscape trapping unit further includes:
[0025] The mounting frame is set on two mounting shafts, and the other end of the upper mesh bag and the other end of the lower mesh bag are both set on the mounting frame.
[0026] The mounting plate is mounted on one of the mounting shafts, and a torsion spring is also mounted on the mounting shaft. One end of the torsion spring is mounted on the mounting plate, and the other end of the torsion spring is mounted on one of the fixed brackets.
[0027] In a preferred embodiment, the landscape trapping unit further includes:
[0028] The gear component is mounted on another mounting shaft.
[0029] A general-purpose motor is mounted on another fixed bracket. The output shaft of the general-purpose motor is connected to a toothed gear via a coupling. The toothed gear meshes with a gear component.
[0030] In a preferred embodiment, the landscape trapping unit further includes:
[0031] A swing threaded seat is provided at the other end of the lower mesh bag, and a buffer pad ring is provided on the swing threaded seat;
[0032] A collection box is mounted on a swing threaded seat.
[0033] Two elastic pull ropes are provided, both of which are mounted on the swing threaded seat, and one end of each elastic pull rope is mounted on the inner wall of the swing chamber.
[0034] In a preferred embodiment, the rainwater reuse module further includes:
[0035] The upper frame is set on the upper light post;
[0036] The collection chamber is located inside the installation cavity, and a filter plate frame is provided on the collection chamber, with the upper plate frame located above the filter plate frame.
[0037] In a preferred embodiment, the rainwater reuse module further includes:
[0038] A delivery pump is installed on the collection chamber, and the delivery pump is located inside the mounting cavity. The output end of the delivery pump is provided with a water supply chamber.
[0039] Multiple reuse pipes are installed on the water supply chamber, and the installation water ring is installed on the multiple reuse pipes, with multiple reuse ports opened on the installation water ring.
[0040] In a preferred embodiment, the rainwater reuse module further includes:
[0041] Multiple flushing pipes are installed on the water supply chamber, and multiple self-flushing nozzles are respectively installed on the output end of the multiple flushing pipes. The multiple self-flushing nozzles are all located inside the collection chamber.
[0042] There are two drain outlets, both of which are located on the upper lamp post and are connected to the interior of the mounting cavity.
[0043] As can be seen from the above, the energy-saving smart lighting device for scenic areas provided by the present invention has the effect of improving the mosquito trapping effect of scenic area lighting devices. During the lighting trapping, the device can shake and clean the dead and dried insects from the inner wall of the net bag and the mesh, so as to avoid the dried insects clogging the mesh, thereby ensuring the airflow during the trapping operation and ensuring the trapping effect. At the same time, cleaning up the accumulated insect corpses can prevent them from causing secondary insect damage. Attached Figure Description
[0044] Figure 1 This is a schematic diagram of the overall structure of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0045] Figure 2 This is a schematic diagram of the smart camera mechanism and photovoltaic panel combination structure of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0046] Figure 3 This is a schematic diagram of the disassembled structure of the dustproof ring frame and photovoltaic support of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0047] Figure 4 This is a schematic diagram of the landscape trapping unit structure of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0048] Figure 5 This is a schematic diagram of the combined structure of a retractable bucket and a mosquito frame for an energy-saving smart lighting device for scenic areas proposed in this invention.
[0049] Figure 6 This is a schematic diagram of the combined structure of the lower and upper mesh bags of an energy-saving smart lighting device for scenic areas proposed in this invention.
[0050] Figure 7 This is a schematic diagram of the installation frame and the swing threaded seat combination structure of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0051] Figure 8 This is a schematic diagram of the rainwater reuse module structure of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0052] Figure 9 This is a schematic diagram of the combined structure of the water ring and filter plate frame for the installation of an energy-saving smart lighting device for scenic areas proposed in this invention;
[0053] Figure 10 This is a schematic diagram of the self-rinsing nozzle and delivery pump combination structure of an energy-saving smart lighting device for scenic areas proposed in this invention.
[0054] In the diagram: 1. Lighting pole; 2. Soft light cover; 3. Removable net panel; 4. Landscape trapping unit; 401. Active air pump; 402. Connecting chamber; 403. Airflow pipe; 404. Airflow nozzle; 405. Trapping lamp body; 406. Insect frame; 407. Fixing bracket; 408. Lower net bag; 409. Upper net bag; 410. Fixing ring frame; 411. Guide plate; 412. Converging hopper; 413. Swinging threaded seat; 414. Collection box; 415. Elastic pull rope; 416. Mounting frame; 417. Mounting plate; 418. Torsion spring; 419. Mounting shaft; 420. Buffer ring. ; 421. General-purpose motor; 422. Gear with missing teeth; 423. Gear component; 424. Diverting hopper; 5. Fixed pole; 6. Upper lamp post; 7. Rainwater reuse module; 701. Upper frame; 702. Collection chamber; 703. Reuse pipe; 704. Water supply chamber; 705. Filter plate frame; 706. Water ring installation; 707. Flushing pipe; 708. Self-flushing nozzle; 709. Reuse port; 710. Transfer pump; 711. Drain outlet; 8. Lamp wick; 9. Shaking chamber; 10. Smart camera mechanism; 11. Photovoltaic panel; 12. Air inlet chamber; 13. Photovoltaic bracket; 14. Dustproof ring frame; 15. Installation chamber. Detailed Implementation
[0055] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.
[0056] The present invention discloses an energy-saving smart lighting device for scenic spots, which is mainly used in scenarios where the dried bodies of dead mosquitoes can easily cause mesh blockage, thereby obstructing the airflow channel, reducing the mosquito-trapping efficiency, and the long-term accumulation of insect corpses in humid environments can easily become damp and moldy, breed bacteria, and cause secondary insect infestations.
[0057] Reference Figures 1-10 An energy-saving smart lighting device for scenic areas includes:
[0058] A lighting pole 1 is provided with a lamp wick 8 and a diffuser 2. The lamp wick 8 is located inside the diffuser 2.
[0059] Two disassembly mesh panels 3 are provided on the lighting pole 1, and a shaking chamber 9 is provided on the lighting pole 1.
[0060] Multiple fixed poles 5 are all set on the lighting pole 1. The multiple fixed poles 5 are equipped with the same upper lamp post 6. The upper lamp post 6 has an installation cavity 15 and an air inlet cavity 12.
[0061] A dustproof ring frame 14 is installed on the upper lamp post 6. A photovoltaic bracket 13 is also installed on the upper lamp post 6. Multiple photovoltaic panels 11 are installed on the photovoltaic bracket 13.
[0062] The smart camera module 10 is mounted on the upper lamp post 6.
[0063] The landscape trapping unit 4 is set on the upper light post 6, the lighting post 1 and multiple fixed poles 5. The landscape trapping unit 4 includes a retractable bucket 412, an upper net bag 409 and a lower net bag 408, with the upper net bag 409 located above the lower net bag 408.
[0064] Rainwater reuse module 7 is mounted on the upper lamp post 6. Rainwater reuse module 7 includes multiple self-washing nozzles 708 and a water ring 706.
[0065] Reference Figures 1-7 In a preferred embodiment, the landscape trapping unit 4 further includes:
[0066] A connecting chamber 402 is located inside the air intake chamber 12, and an active air pump 401 is installed on the connecting chamber 402.
[0067] Multiple airflow pipes 403 are installed on the connecting chamber 402. Each airflow pipe 403 has an airflow nozzle 404 at its output end. Each airflow nozzle 404 is installed on the upper lamp post 6. The smart camera unit 10 is located between the multiple airflow nozzles 404.
[0068] In this invention, the landscape trapping unit 4 further includes:
[0069] A fixed ring frame 410 is mounted on multiple fixed uprights 5. A trapping lamp body 405 is mounted on the fixed ring frame 410 and is located below the smart camera structure 10.
[0070] Guide plate 411, guide plate 411 is mounted on fixed ring frame 410;
[0071] The mosquito frame 406 is mounted on the lighting pole 1, the retractable bucket 412 is mounted on the mosquito frame 406, the guide plate 411 is located above the retractable bucket 412, and the retractable bucket 412 is also provided with multiple installation ports.
[0072] In this invention, the landscape trapping unit 4 further includes:
[0073] Multiple diversion buckets 424 are respectively set on multiple installation ports. One end of the upper net bag 409 is set on the mosquito frame 406. The upper net bag 409 and the lower net bag 408 are both located inside the shaking chamber 9.
[0074] Two fixed brackets 407 are provided inside the shaking chamber 9, and each fixed bracket 407 is provided with a mounting shaft 419.
[0075] In this invention, the landscape trapping unit 4 further includes:
[0076] Mounting frame 416 is mounted on two mounting shafts 419. The other end of the upper net bag 409 and the other end of the lower net bag 408 are both mounted on the mounting frame 416.
[0077] Mounting plate 417 is mounted on one of the mounting shafts 419. A torsion spring 418 is also mounted on the mounting shaft 419. One end of the torsion spring 418 is mounted on the mounting plate 417, and the other end of the torsion spring 418 is mounted on one of the fixed brackets 407.
[0078] In this invention, the landscape trapping unit 4 further includes:
[0079] Gear component 423 is mounted on another mounting shaft 419;
[0080] A general-purpose motor 421 is mounted on another fixed bracket 407. The output shaft of the general-purpose motor 421 is connected to a toothed gear 422 via a coupling. The toothed gear 422 meshes with a gear component 423.
[0081] In this invention, the landscape trapping unit 4 further includes:
[0082] A swing threaded seat 413 is provided at the other end of the lower mesh bag 408, and a buffer pad ring 420 is provided on the swing threaded seat 413.
[0083] Collection box 414 is disposed on the swing thread seat 413;
[0084] Two elastic pull ropes 415 are provided on the swing thread seat 413, and one end of each elastic pull rope 415 is provided on the inner wall of the shaking chamber 9.
[0085] Specifically, during the illumination trapping process, the trapping lamp body 405 operates to trap mosquitoes in the scenic area. When mosquitoes reach the vicinity of the trapping lamp, since the active air pump 401 is in operation, the active air pump 401 can deliver airflow to the airflow nozzle 404 through the airflow pipe 403 and the connecting chamber 402, and spray airflow to actively capture mosquitoes. The airflow blows the mosquitoes into the guide plate 411, and further guides them into the shrinking bucket 412 and the mosquito frame 406 (the diversion bucket 424 can divert the airflow to blow against the inner wall of the mosquito frame 406, preventing mosquitoes from hiding in the dead corner of the shrinking bucket 412), thereby killing the mosquitoes as they dry.
[0086] After the mosquitoes are dried, the general-purpose motor 421 is activated, driving the toothed gear 422 to rotate. Since the toothed gear 422 meshes with the gear component 423, it can drive the gear component 423, the mounting shaft 419, and the mounting frame 416 to rotate, causing the torsion spring 418 to twist and deform. At the same time, since the toothed gear 422 and the gear component 423 can periodically mesh and disengage, when disengaging, the torsion spring 418 can drive the mounting frame 416 to twist and reset, which in turn causes the mounting frame 416 to violently swing the upper net bag 409 and the lower net bag 408 to shake off the dead insects and put them into the collection box 414. Afterwards, the scenic area maintenance personnel regularly disassemble the collection box 414 for cleaning to complete the mosquito trapping operation.
[0087] In specific application scenarios, the landscape trapping unit 4 is suitable for the trapping operation of scenic lighting devices. When trapping with lighting, the landscape trapping unit 4 can drive the soft upper net bag 409 and lower net bag 408 to produce intermittent rapid reset swing through the periodic meshing and separation of the toothed gear 422 and gear 423, combined with the energy storage and instantaneous release of the torsion spring 418. This generates an impact effect similar to swinging or shaking, which shakes and cleans the dead and dried insects from the inner wall of the net bag and the mesh. During the violent swing, the soft upper net bag 409 and lower net bag 408 will also undergo instantaneous deformation, and the geometry of the mesh will change accordingly. This effectively destroys the adhesion interface between the dried insect carcasses and the net, allowing the insect carcasses to be quickly peeled off and fall off the surface of the net frame, so as to avoid the dried insects clogging the mesh. This ensures the airflow during the trapping operation and guarantees the trapping effect. At the same time, cleaning up the accumulated insect carcasses can prevent secondary insect damage.
[0088] It should be noted that regularly throwing the dead insects on the net bag into the collection box 414 below can keep the mesh of the net bag unobstructed, ensuring that the airflow for drying is not reduced due to the mesh being blocked. This allows the insects to be efficiently pressed into the net bag and dried quickly, forming an efficient and virtuous cycle. The special shape of the shrinking hopper 412 can increase the airflow speed here and prevent the insects from escaping.
[0089] The dried carcasses will eventually fall into individual collection boxes 414 instead of being scattered, which simplifies the work of the scenic area maintenance staff from "laboriously scrubbing the adhesive mesh frame" to "regularly emptying the collection boxes 414", further improving the effectiveness of the device.
[0090] The bottom of the swing threaded seat 413 is provided with an elastic pull rope 415. When swinging, the elastic pull rope 415 can absorb a certain amount of vibration and provide flexible suspension. At the same time, in conjunction with the buffer pad ring 420, it can prevent the swing threaded seat 413 from directly contacting and colliding with the interior of the lighting column 1 to generate noise.
[0091] Reference Figure 1 , Figure 3 , Figure 8 , Figure 9 and Figure 10 In a preferred embodiment, the rainwater reuse module 7 further includes:
[0092] Upper frame 701, the upper frame 701 is set on the upper lamp post 6;
[0093] Collection chamber 702 is located inside the mounting cavity 15. A filter plate frame 705 is provided on the collection chamber 702, and an upper plate frame 701 is located above the filter plate frame 705.
[0094] In this invention, the rainwater reuse module 7 further includes:
[0095] A delivery pump 710 is installed on the collection chamber 702. The delivery pump 710 is located inside the mounting cavity 15. A water supply chamber 704 is provided at the output end of the delivery pump 710.
[0096] Multiple reuse pipes 703 are installed on the water supply chamber 704. A water ring 706 is installed on the multiple reuse pipes 703, and multiple reuse ports 709 are opened on the water ring 706.
[0097] In this invention, the rainwater reuse module 7 further includes:
[0098] Multiple flushing pipes 707 are installed on the water supply chamber 704, and multiple self-flushing nozzles 708 are installed on the output ends of the multiple flushing pipes 707. The multiple self-flushing nozzles 708 are located inside the collection chamber 702.
[0099] Two drain outlets 711 are provided on the upper lamp post 6, and both drain outlets 711 are connected to the interior of the mounting cavity 15.
[0100] Specifically, during rainwater harvesting and utilization, rainwater can be collected through the collection chamber 702. At the same time, during rainwater collection, the device can filter large-volume debris and small-volume impurities through the upper plate frame 701 and the filter plate frame 705 respectively, so as to complete the rainwater collection.
[0101] When rainwater is reused, the delivery pump 710 operates, which can deliver rainwater to the water supply chamber 704 and further deliver it into the reuse pipe 703 and the flushing pipe 707. The rainwater entering the reuse pipe 703 will further enter the water ring 706 and be discharged from the reuse port 709 to clean the surface of the photovoltaic panel 11. The rainwater entering the flushing pipe 707 is sprayed out by the self-flushing nozzle 708 to backwash the filter plate frame 705 and allow the impurities washed down to be discharged from the drain port 711, ensuring the cleanliness of the filter plate frame 705 during subsequent rainwater collection and ensuring the collection effect.
[0102] In specific application scenarios, the rainwater reuse module 7 is suitable for the rainwater utilization of lighting devices. That is, the rainwater reuse module 7 can help rainwater actively remove accumulated dust, keep the photovoltaic modules at a high photoelectric conversion efficiency, ensure the independent power supply capability of the lighting device, and use natural precipitation as a working medium without consuming municipal water resources. At the same time, the cleaned water can be infiltrated back to irrigate green spaces, forming an environmentally friendly water resource cycle and improving the use effect of the device.
[0103] It should be noted that the filter plate frame 705 can be backwashed by the self-washing nozzle 708 during use, which solves the problem of easy clogging of the filter screen during rainwater collection, ensures long-term stable operation of the system, and reduces the workload of manually cleaning the photovoltaic panel 11 and the filter screen by reusing rainwater.
[0104] Working principle:
[0105] When the light traps mosquitoes, the trapping lamp body 405 operates to trap mosquitoes in the scenic area. When mosquitoes reach the vicinity of the trapping lamp, the active air pump 401 is in operation. Therefore, the active air pump 401 can deliver airflow to the airflow nozzle 404 through the airflow pipe 403 and the connecting chamber 402, and spray airflow to actively capture mosquitoes. The airflow blows the mosquitoes into the guide plate 411, and further guides them into the shrinking hopper 412 and the mosquito frame 406, where they are killed as they dry.
[0106] After the mosquitoes are dried, the general-purpose motor 421 is activated, driving the toothed gear 422 to rotate. Since the toothed gear 422 meshes with the gear component 423, it can drive the gear component 423, the mounting shaft 419, and the mounting frame 416 to rotate, causing the torsion spring 418 to twist and deform. At the same time, since the toothed gear 422 and the gear component 423 can periodically mesh and disengage, when disengaging, the torsion spring 418 can drive the mounting frame 416 to twist and reset, which in turn causes the mounting frame 416 to violently swing the upper net bag 409 and the lower net bag 408 to shake off the dead insects and put them into the collection box 414. Afterwards, the scenic area maintenance personnel regularly disassemble the collection box 414 for cleaning to complete the mosquito trapping operation.
[0107] When collecting and utilizing rainwater, rainwater can be collected through the collection chamber 702. At the same time, when collecting rainwater, the device can filter large-volume debris and small-volume impurities through the upper plate frame 701 and the filter plate frame 705 respectively, so as to complete the collection of rainwater.
[0108] When rainwater is reused, the delivery pump 710 operates, which delivers rainwater to the water supply chamber 704 and further into the reuse pipe 703 and the flushing pipe 707. The rainwater entering the reuse pipe 703 enters the water ring 706 and is discharged from the reuse port 709 to clean the surface of the photovoltaic panel 11. The rainwater entering the flushing pipe 707 is sprayed out by the self-flushing nozzle 708 to backwash the filter frame 705 and allow the impurities washed down to be discharged from the drain port 711, ensuring the cleanliness of the filter frame 705 during subsequent rainwater collection and guaranteeing the collection effect.
[0109] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.
Claims
1. An energy-saving smart lighting device for scenic areas, characterized in that, include: A lighting post (1) is provided with a lamp core (8), and a soft light cover (2) is also provided on the lighting post (1), with the lamp core (8) located inside the soft light cover (2); Two disassembly mesh plates (3) are provided on the lighting pole (1), and the lighting pole (1) is provided with a shaking chamber (9). Multiple fixed poles (5) are provided on the lighting pole (1). The multiple fixed poles (5) are provided with the same upper lamp post (6). The upper lamp post (6) is provided with an installation cavity (15) and an air inlet cavity (12). Dustproof ring frame (14) is set on the upper lamp post (6), and the upper lamp post (6) is also provided with a photovoltaic bracket (13), and multiple photovoltaic panels (11) are set on the photovoltaic bracket (13). The intelligent camera module (10) is installed on the upper lamp post (6); The landscape trapping unit (4) is set on the upper lamp post (6), the lighting lamp post (1) and multiple fixed poles (5). The landscape trapping unit (4) includes a shrink bucket (412), an upper net bag (409) and a lower net bag (408). The upper net bag (409) is located above the lower net bag (408). Rainwater reuse module (7) is installed on the upper lamp post (6). The rainwater reuse module (7) includes multiple self-washing nozzles (708) and a water ring (706).
2. The energy-saving smart lighting device for scenic areas according to claim 1, characterized in that, The landscape trapping unit (4) also includes: A connecting chamber (402) is provided inside the air inlet chamber (12), and an active air pump (401) is provided on the connecting chamber (402). Multiple airflow pipes (403) are provided on the connecting chamber (402). Each of the multiple airflow pipes (403) has an airflow nozzle (404) at its output end. Each of the multiple airflow nozzles (404) is provided on the upper lamp post (6). The smart camera unit (10) is located between the multiple airflow nozzles (404).
3. The energy-saving smart lighting device for scenic areas according to claim 2, characterized in that, The landscape trapping unit (4) also includes: A fixed ring frame (410) is set on multiple fixed uprights (5). A trapping lamp body (405) is set on the fixed ring frame (410). The trapping lamp body (405) is located below the smart camera structure (10). Guide plate (411), guide plate (411) is mounted on fixed ring frame (410); The mosquito frame (406) is set on the lighting pole (1), the shrink bucket (412) is set on the mosquito frame (406), the guide plate (411) is located above the shrink bucket (412), and the shrink bucket (412) is also provided with multiple installation ports.
4. The energy-saving smart lighting device for scenic areas according to claim 3, characterized in that, The landscape trapping unit (4) also includes: Multiple diversion buckets (424) are respectively set on multiple installation ports. One end of the upper net bag (409) is set on the mosquito frame (406). The upper net bag (409) and the lower net bag (408) are both located inside the shaking chamber (9). Two fixed supports (407) are provided inside the shaking chamber (9), and each of the two fixed supports (407) is provided with a mounting shaft (419).
5. The energy-saving smart lighting device for scenic areas according to claim 4, characterized in that, The landscape trapping unit (4) also includes: The mounting frame (416) is mounted on two mounting shafts (419), and the other end of the upper mesh bag (409) and one end of the lower mesh bag (408) are both mounted on the mounting frame (416). Mounting disc (417) is mounted on one of the mounting shafts (419). The mounting shaft (419) is also provided with a torsion spring (418). One end of the torsion spring (418) is mounted on the mounting disc (417), and the other end of the torsion spring (418) is mounted on one of the fixed brackets (407).
6. The energy-saving smart lighting device for scenic areas according to claim 5, characterized in that, The landscape trapping unit (4) also includes: Gear component (423), gear component (423) is mounted on another mounting shaft (419); A general-purpose motor (421) is mounted on another fixed bracket (407). The output shaft of the general-purpose motor (421) is connected to a toothed gear (422) via a coupling. The toothed gear (422) meshes with a gear component (423).
7. The energy-saving smart lighting device for scenic areas according to claim 6, characterized in that, The landscape trapping unit (4) also includes: A swing threaded seat (413) is provided at the other end of the lower mesh bag (408), and a buffer pad ring (420) is provided on the swing threaded seat (413). Collection box (414) is disposed on the swing thread seat (413); Two elastic pull ropes (415) are provided on the swing thread seat (413), and one end of each elastic pull rope (415) is provided on the inner wall of the shaking chamber (9).
8. The energy-saving smart lighting device for scenic areas according to claim 1, characterized in that, The rainwater reuse module (7) also includes: The upper frame (701) is set on the upper lamp post (6); Collection chamber (702) is located inside the installation cavity (15). A filter plate frame (705) is provided on the collection chamber (702), and an upper plate frame (701) is located above the filter plate frame (705).
9. The energy-saving smart lighting device for scenic areas according to claim 8, characterized in that, The rainwater reuse module (7) also includes: A delivery pump (710) is installed on the collection chamber (702). The delivery pump (710) is located inside the mounting cavity (15). The output end of the delivery pump (710) is provided with a water supply chamber (704). Multiple reuse pipes (703) are installed on the water supply chamber (704). The installation water ring (706) is installed on the multiple reuse pipes (703) and multiple reuse ports (709) are opened on the installation water ring (706).
10. The energy-saving smart lighting device for scenic areas according to claim 9, characterized in that, The rainwater reuse module (7) also includes: Multiple flushing pipes (707) are provided on the water supply chamber (704), and multiple self-flushing nozzles (708) are respectively provided on the output end of the multiple flushing pipes (707). The multiple self-flushing nozzles (708) are located inside the collection chamber (702). Two drain outlets (711) are provided on the upper lamp post (6) and are connected to the interior of the mounting cavity (15).