CN109717173B

CN109717173B - Automatic spraying mosquito eradication system for disease medium aedes

Info

Publication number: CN109717173B
Application number: CN201910099946.0A
Authority: CN
Inventors: 任东升; 刘起勇; 苏明照; 王君; 宋秀平; 黄汝婷; 吴海霞; 郭玉红; 鲁亮; 孟凤霞; 李贵昌; 栗冬梅; 刘小波; 岳玉娟; 赵宁; 王雪霜
Original assignee: National Institute for Communicable Disease Control and Prevention of Chinese Center For Disease Control and Prevention
Current assignee: National Institute for Communicable Disease Control and Prevention of Chinese Center For Disease Control and Prevention
Priority date: 2019-01-31
Filing date: 2019-01-31
Publication date: 2024-03-01
Anticipated expiration: 2039-01-31
Also published as: CN109717173A

Abstract

The embodiment of the invention relates to the field of mosquito killing equipment, and provides an automatic spraying mosquito killing system for disease vector aedes, which comprises the following components: the device comprises a mosquito density monitoring module, a central control module and an ultra-low capacity spraying module; the central control module receives the mosquito density data in the environment transmitted by the mosquito density monitoring module, compares and judges, and outputs a start control command to the ultra-low-volume spraying module to start spraying when the acquired mosquito density data is greater than or equal to a set density threshold value. The automatic spraying mosquito eradication system for the disease medium aedes provided by the embodiment of the invention can spray and kill mosquitoes with ultra-low capacity in the mosquito activity peak period, so that the accurate mosquito eradication is realized, the mosquito eradication efficiency is effectively improved, the use cost of pesticides is reduced, and the harm of the pesticides to human bodies is reduced.

Description

Automatic spraying mosquito eradication system for disease medium aedes

Technical Field

The embodiment of the invention relates to the field of mosquito eradication equipment, in particular to an automatic spraying mosquito eradication system for disease medium aedes.

Background

Aedes are important disease-bearing organisms that transmit dengue fever, zika, yellow fever, chikungunya fever, and other diseases. The traditional aedes control method mainly comprises detention spraying and ultralow-volume spraying, as the medium aedes are mainly moved outdoors, the outdoor detention spraying is easy to wash by rain and is difficult to cover all mosquito moving areas, the mosquito control effect is poor, the ultralow-volume spraying has the characteristics of small fog drops, large diffusion range and small dosage, the killing speed is high, the application is wide, however, the ultralow-volume spraying has poor lasting effect, the mosquitoes are not thoroughly killed, and the mosquitoes in flying are mainly killed, so that the mosquito density can be controlled only by repeatedly spraying the pesticide in the environment with complex and easy mosquitoes breeding and hiding places with more places. The aedes are unevenly distributed in a community or village, and have high local mosquito density and low local mosquito density, so that the mosquito control in key areas is a main measure for the aedes prevention and control. The specific measures are that the ultra-low volume sprayer is placed in a key area, and the ultra-low volume sprayer is sprayed in the peak period of mosquito activities according to the monitoring result of the mosquito density, so that the aim of rapidly reducing the mosquito density is fulfilled.

Disclosure of Invention

The embodiment of the invention provides an automatic spraying mosquito eradication system for aedes with disease medium, which is used for solving the problems of poor mosquito eradication effect and high consumption of the traditional ultralow-volume spraying device.

The embodiment of the invention provides an automatic spraying mosquito eradication system for aedes with disease vector, which comprises the following components: the device comprises a mosquito density monitoring module, a central control module and an ultra-low capacity spraying module; the central control module receives the mosquito density data in the environment transmitted by the mosquito density monitoring module, compares and judges, and outputs a start control command to the ultra-low-volume spraying module to start spraying when the acquired mosquito density data is greater than or equal to a set density threshold value.

Further, the density threshold is in the range of 0.01-10 pieces/min.

Further, the mosquito density monitoring module includes: the device comprises an acquisition module, a timing module and a data processing module; the timing module is electrically connected with the data processing module and transmits real-time data to the data processing module; the acquisition module is electrically connected with the data processing module or in wireless transmission connection, and the acquired mosquito quantity data in the environment are transmitted to the data processing module; and the data processing module receives the mosquito quantity data and the time data at the same time and processes the mosquito quantity data and the time data to obtain the mosquito density data.

Further, the mosquito density monitoring module further includes: the mosquito trapper is internally provided with a mosquito attractant and the acquisition module.

Further, the mosquito trapper includes a plurality of, and every set up respectively the mosquito trapper one collection module, every collection module connects a wireless transmission module, through wireless transmission will the mosquito quantity data transmission who obtains to in the data processing module.

Further, the ultra-low volume spray module comprises: an ultra-low volume atomizer and a rotating base; the central control module outputs a control command to control the ultra-low volume sprayer to start or stop; the ultra-low volume sprayer is arranged on the rotating base and horizontally rotates along with the rotating base.

Further, the nozzle of the ultra-low volume sprayer is arranged in a horizontal upward inclined mode, and the inclined angle is 0-90 degrees.

Further, a switch socket is arranged on the top or the side edge of the rotary platform, a waterproof cover made of plastic materials is sleeved outside the switch socket, and the waterproof cover is provided with a through hole corresponding to the jack of the switch socket.

Further, the swivel base includes: a rotary platform connected and driven by a rotary shaft of the motor and a power supply assembly for supplying power; the top of the rotating platform is provided with a containing groove for placing the ultra-low volume sprayer; the power interface of the power supply assembly is inserted into the accommodating groove from the bottom of the rotary platform; the power plug of the ultra-low volume sprayer is arranged at the bottom of the power plug and is inserted into the accommodating groove to be correspondingly and electrically connected with the power interface.

Further, the mosquito density monitoring device comprises a plurality of mosquito traps, each mosquito trap is provided with one acquisition module, each acquisition module is connected with a wireless transmission module, and acquired mosquito quantity data are transmitted to the data processing module for data processing through wireless transmission; the mosquito traps are uniformly arranged in the mosquito monitoring area, and each mosquito trap is respectively provided with a wireless control switch door; the ultra-low volume spraying module is arranged in the middle of the mosquito monitoring area.

According to the automatic spraying mosquito eradication system for the aedes with the disease vector, the density threshold value is set for the central control module in advance, the central control module compares and judges the mosquito density data transmitted by the mosquito density monitoring module with the set density threshold value when receiving the mosquito density data, and when the acquired mosquito density data is greater than or equal to the set density threshold value, a starting control command is output to the ultralow-volume spraying module to start spraying, so that the ultralow-volume spraying mosquito eradication can be performed during the mosquito activity peak period, the accurate mosquito eradication efficiency is realized, the use cost of the pesticide is reduced, and the harm of the pesticide to human bodies is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a circuit control module of an embodiment of an automatic spray mosquito eradication system for aedes disease media according to the present invention;

fig. 2 is a schematic structural diagram of an embodiment of a mosquito density monitoring module according to the present invention;

FIG. 3 is a schematic diagram of an embodiment of an ultra-low volume spray module according to the present invention.

Wherein:

1-a mosquito trap; 11-a mosquito inlet; 100-mosquito density monitoring module; 200-a central control module; 300-ultra low volume spray module; 101-an acquisition module; 102-a timing module; 103-a data processing module; 104-an attracting module; 105-a wireless transmission module; 301-ultra low volume nebulizer; 302-rotating the base; 3021-rotating a platform; 3021 a-accommodating grooves; 3022-supporting frames; 3023-an electric motor; 3024-a power supply assembly.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

FIG. 1 is a schematic diagram of an embodiment of an automatic spray mosquito eradication system for aedes disease media according to the present invention, as shown in FIG. 1, comprising: comprising the following steps: a mosquito density monitoring module 100, a central control module 200, and an ultra-low volume spraying module 300. Wherein:

the central control module 200 receives the mosquito density data transmitted by the mosquito density monitoring module 100, performs comparison and judgment, outputs a start control command to the ultra-low volume spraying module 300 to start spraying when the acquired mosquito density data is greater than or equal to a set density threshold, and outputs a stop control command to the ultra-low volume spraying module 300 to stop spraying when the acquired mosquito density data is lower than the set density threshold.

Specifically, the mosquito density monitoring module 100 is mainly used for monitoring the number of mosquitoes in the surrounding environment of the mosquito killing system, and the mosquito density monitoring device known to those skilled in the art can be adopted to directly monitor and acquire the mosquito density data in the surrounding environment.

In another embodiment, the present invention provides a modular mosquito density monitoring module 100 configuration, the mosquito density monitoring module 100 further comprising: the system comprises an acquisition module 101, a timing module 102 and a data processing module 103; the acquisition module 101 and the timing module 102 are electrically connected with the data processing module 103, respectively.

The acquisition module 101 is configured to detect the number of mosquitoes in the environment, and by using a mosquito detection device known to those skilled in the art, such as an infrared sensor, the number of mosquitoes can be obtained in real time through biological sensing and converted into signals to be transmitted to the data processing module 103, and the timing module 102 transmits time data to the data processing module 103 in real time when the mosquito acquisition starts.

The data processing module 103 uses a general processor, such as a CPU, etc., which is conventional in the art to receive the mosquito number data and the time data at the same time, and performs calculation to obtain the mosquito density data.

Fig. 2 is a schematic structural diagram of an embodiment of a mosquito density monitoring module according to the present invention. In order to improve mosquito killing efficiency, in another embodiment, the invention adds the attracting module 104 to the modularized mosquito density monitoring module 100, specifically, as shown in fig. 2, the mosquito density monitoring module 100 further includes: the mosquito trapper 1, the mosquito trapper 1 is internally provided with a mosquito attractant, the acquisition module 101 is arranged in the mosquito trapper 1, the timing module 102 and the data processing module 103 can be integrated on the same circuit board together with the central control module 200, and the mosquito trapper is internally arranged in the ultra-low-volume spraying device. The mosquito attractant collects mosquitoes in the surrounding environment in the mosquito trapper 1, acquires the number of the mosquitoes in the mosquito trapper 1 in real time through biological induction (infrared inductor), can accelerate the monitoring and the mosquito density of the mosquitoes, and improves the mosquito killing efficiency. In order to improve trapping efficiency, a plurality of mosquito traps 1 can be arranged to trap mosquitoes simultaneously, an acquisition module 101 is arranged in each mosquito trap 1 to acquire the number of the mosquitoes, meanwhile, each acquisition module 101 can be connected with a wireless transmission module 105, the number data of the mosquitoes acquired by each acquisition module 101 are transmitted to a data processing module 103 in a wireless mode through the wireless transmission module 105, and the data processing module 103 receives time data and the total number data of the mosquitoes simultaneously, so that data processing is performed to acquire the density data of the mosquitoes. Further, in order to facilitate the entry of mosquitoes into the container, a plurality of mosquito inlets 11 are provided on the top cover of the mosquito trap 1.

The ultra-low volume spraying module 300 is a spraying execution body of the mosquito eradication system, and executes different working states after receiving a control command output by the central control module 200. Generally, an ultralow volume spraying device commonly used in the art is adopted, where the mosquito density monitoring module 100 and the central control module 200 can be integrated into an ultralow volume spraying device to form an integrated device, and can also be used as a separate device, for example, the mosquito density monitoring module 100 adopts a mosquito density monitoring device separated from the ultralow volume spraying device, the central control module 200 is integrated into the ultralow volume spraying device, and the mosquito density monitoring device performs wireless data and signal transmission with the central control module 200 by setting a wireless transmission module 105.

In addition, because mosquito trapper 1 can directly trap and collect the mosquito, then can place the ultralow volume atomizer in mosquito trapper 1, trap the mosquito through attracting module 104 to container 1 in, central control module integrated in the ultralow volume atomizer, control ultralow volume atomizer and spray the kill mosquito.

Secondly, the mosquito density monitoring module 100 may be provided with a plurality of mosquito traps 1, preferably 1-30 mosquito traps 1, and each mosquito trap 1 is respectively provided with an acquisition module 101, each acquisition module 101 is connected with a wireless transmission module 105, and the acquired mosquito quantity data is transmitted to the data processing module 103 for data processing through wireless transmission. The mosquito traps 1 are designed to be in annular arrangement, and each mosquito trap 1 is respectively provided with a wireless control switch door; the ultra-low volume spray module 300 is disposed in the middle of the ring shape surrounded by the plurality of mosquito traps 1, and preferably each mosquito trap 1 is spaced from the ultra-low volume spray module 300 by a linear distance of not more than 100 meters. The wireless control switch door can be controlled by the central control module 200, when the density of mosquitoes reaches or exceeds the density threshold value, the central control module 200 outputs control commands to the control switch door to start to open, mosquitoes in the mosquito trap 1 fly out from the control switch door, and the ultra-low-volume spraying device is started to spray and kill mosquitoes in a rotating mode. The structure can realize centralized mosquito killing, and greatly improves the mosquito killing efficiency and the use rate of the sprayer.

The central control module 200 is used as a control core of the whole mosquito eradication system, and can be programmed by a conventional controller in the art, such as a PLC or a single chip microcomputer, and generally includes a central processing module, an analog input/output module, a digital input/output module, a data storage module, a network communication module, and the like, and can be programmed by using programming software according to specific use requirements.

According to the mosquito killing system, the density threshold value is set for the central control module 200 in advance, when the central control module 200 receives the mosquito density data transmitted by the mosquito density monitoring module 100, the mosquito density data is compared with the set density threshold value, and when the acquired mosquito density data is greater than or equal to the set density threshold value, a starting control command is output to the ultralow-volume spraying module 300 to start spraying, namely, the mosquito killing system starts spraying to kill mosquitoes only when the mosquito density is greater (namely, the mosquito activity peak period), so that the precision mosquito killing can be realized, the mosquito killing efficiency is effectively improved, meanwhile, the ultralow-volume spraying mosquito killing is realized, the use cost is saved, and the harm of the mosquito killing agent to human bodies is reduced. The automatic spraying mosquito eradication system for the disease medium aedes can be placed in places with more mosquitoes and more hidden places in advance when in use, for example, the distribution of the aedes in a community or village is uneven, the density of the aedes in the places is high, and the density of the mosquitoes in the places is low, so that the automatic spraying mosquito eradication system for the disease medium aedes can be placed in the important areas of the aedes, and can perform ultra-low-volume spraying in the peak period of the mosquito activity according to the monitoring result of the density of the mosquitoes, thereby achieving the purpose of rapidly reducing the aedes.

The duration of each spraying of the mosquito eradication system can be set arbitrarily by people according to the type of the sprayer. In order to avoid the waste of insecticide and improve the service life and efficiency of the sprayer, the central control module 200 can set that when the mosquito density monitoring device detects that the mosquito density data is lower than the set density threshold value, a stop control command is output to the ultra-low volume spraying module 300 to stop the spraying process. Further, the spraying time after the ultra-low volume spraying module 300 starts spraying may be set according to the droplet size and flow rate of the ultra-low volume spraying module 300, preferably in the range of 1-15 minutes, for example, after each start of spraying to kill mosquitoes, spraying is set for 2 minutes and then stopped.

The above-mentioned density threshold can be set arbitrarily according to the needs of different environments, and its preferred threshold range is 0.01-10 mosquitoes/min, for example, the density threshold is set to 1/5 min, i.e. every 5 min, the collecting module 101 can start mosquito killing for a total of 1 mosquito; or, setting the density threshold to be 5/15 min, namely, every 15 min, the acquisition module 101 can start mosquito killing for a total of 5 mosquitoes; still alternatively, the density threshold is set to 2 mosquitoes/1 minute, that is, every 1 minute, and the collection module 101 can start mosquito killing for a total of 2 mosquitoes.

According to the automatic spraying mosquito eradication system for the aedes with the vector, the density threshold value is set for the central control module 200 in advance, when the central control module 200 receives the mosquito density data transmitted by the mosquito density monitoring module 100, the central control module 200 compares and judges the mosquito density data with the set density threshold value, and when the acquired mosquito density data is greater than or equal to the set density threshold value, a starting control command is output to the ultra-low volume spraying module 300 to start spraying, so that ultra-low volume spraying mosquito eradication can be performed during the peak period of mosquito activity, accurate mosquito eradication is realized, mosquito eradication efficiency is effectively improved, the use cost of pesticides is reduced, and harm of the pesticides to human bodies is reduced.

FIG. 3 is a schematic diagram of an embodiment of an ultra-low volume spray module according to the present invention. In order to expand the mosquito killing range of the ultra-low volume spray module 300, the ultra-low volume spray module 300 of the present invention has a rotating base 302 structure, and specifically, as shown in fig. 3, the ultra-low volume spray module 300 comprises: an ultra-low volume atomizer 301 and a swivel base 302; an ultra-low volume atomizer 301 is disposed on the swivel base 302 and rotates horizontally with the swivel base 302.

The rotating base 302 may be a device capable of horizontally rotating as known in the art, for example, the rotating base 302 is composed of a motor 3023 and a rotating platform 3021, a rotating shaft of the motor 3023 is vertically disposed and rotates around a horizontal direction, a top of the rotating shaft is connected with a bottom of the rotating platform 3021, the rotating platform 3021 is driven to horizontally rotate, when the ultra-low volume sprayer 301 is used, manual spraying and mosquito killing can be independently performed, and the device can be directly disposed on the rotating platform 3021 to spray and kill mosquitoes in 360 degrees in the horizontal direction, so that a mosquito killing range is enlarged, the use efficiency of the sprayer is improved, meanwhile, the cost of manual spraying is reduced, and injury of pesticides to people is reduced. Further, the nozzle of the ultra-low volume sprayer 301 may be horizontally and upwardly inclined, and the inclination angle is 0-90 °, preferably 45 °, so as to further enlarge the mosquito killing area.

On the basis of the above embodiments, in this embodiment, the top or side of the rotary platform 3021 is provided with a switch socket, and a waterproof cover made of plastic material is sleeved outside the switch socket, and the waterproof cover is provided with a through hole corresponding to the jack of the switch socket. The switch socket is arranged at the top of the rotary platform 3021, so that the ultra-low volume sprayer 301 can be conveniently plugged in for use, a waterproof cover is arranged outside the switch socket, and the phenomenon that the spray falls into the switch socket to cause short circuit when the ultra-low volume sprayer 301 performs rotary spraying can be avoided.

On the basis of the above embodiments, this embodiment provides a specific structure of the rotating base 302, where the rotating base 302 includes: a rotary platform 3021 connected and driven by a rotary shaft of the motor 3023 and a power supply assembly 3024 for supplying power; the top of the rotary platform 3021 is provided with a containing groove 3021a for placing the ultra-low volume sprayer 301; the power interface of the power supply assembly 3024 is inserted into the accommodation groove 3021a from the bottom of the rotary platform 3021; the power plug of the ultra-low volume sprayer 301 is disposed at the bottom thereof, and is inserted into the accommodating groove 3021a to be electrically connected to the power interface correspondingly. When in use, the ultra-low volume sprayer 301 is directly inserted into the accommodating groove 3021a, i.e. can be electrically inserted for spraying, and the central control module 200 directly controls the on-off of the power supply assembly 3024, i.e. can control the working state of the ultra-low volume sprayer 301. To avoid water accumulation, a water leakage hole may be provided at the bottom of the accommodation groove 3021 a.

Considering that the motor 3023 and the power supply assembly 3024 are convenient to install, the supporting frame 3022 is arranged below the rotary platform 3021 on the basis of the above embodiments, the motor 3023 and the power supply assembly 3024 are respectively placed and fixed in the supporting frame 3022, and the supporting frame 3022 is externally packaged through an outer cover, so that an integrated product is formed through assembly.

The apparatus embodiments described above are merely illustrative, wherein the units described as separate components may or may not be physically separate. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment. Those of ordinary skill in the art will understand and implement the present invention without undue burden.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims

1. An automatic spray mosquito eradication system for aedes disease medium comprising: the device comprises a mosquito density monitoring module, a central control module and an ultra-low capacity spraying module;

the central control module receives the mosquito density data in the environment transmitted by the mosquito density monitoring module, compares and judges, and outputs a start control command to the ultra-low-volume spraying module to start spraying when the acquired mosquito density data is greater than or equal to a set density threshold value, and after each start of spraying for killing mosquitoes, the spraying is stopped after a preset time; outputting a stopping control command to the ultra-low-volume spraying module to stop spraying when the acquired mosquito density data is lower than a set density threshold value;

the mosquito density monitoring module includes: the device comprises an acquisition module, a timing module and a data processing module;

the timing module is electrically connected with the data processing module and transmits real-time data to the data processing module;

the acquisition module is electrically connected with the data processing module or in wireless transmission connection, and the acquired mosquito quantity data in the environment are transmitted to the data processing module;

the data processing module receives the mosquito quantity data and the time data at the same time and performs data processing to obtain the mosquito density data;

the mosquito density monitoring module further comprises: the mosquito trapper is internally provided with a mosquito attractant and the acquisition module;

the mosquito trappers comprise a plurality of mosquito trappers, each mosquito trapper is provided with one acquisition module, each acquisition module is connected with a wireless transmission module, and acquired mosquito quantity data are transmitted to the data processing module through wireless transmission;

the ultra-low volume spray module includes: an ultra-low volume atomizer and a rotating base; the central control module outputs a control command to control the ultra-low volume sprayer to start or stop;

the ultra-low volume sprayer is arranged on the rotating base and horizontally rotates along with the rotating base;

the mosquito density monitoring device comprises a plurality of mosquito traps, each mosquito trap is provided with a collecting module, each collecting module is connected with a wireless transmission module, and acquired mosquito quantity data are transmitted to the data processing module for data processing through wireless transmission;

the mosquito traps are uniformly arranged in the mosquito monitoring area, and each mosquito trap is respectively provided with a wireless control switch door; the ultra-low volume spraying module is arranged in the middle of the mosquito monitoring area.

2. An automated spray mosquito eradication system for aedes disease media according to claim 1, wherein the density threshold is in the range of 0.01 to 10/min.

3. The automatic spray mosquito eradication system for aedes disease media of claim 1 wherein the nozzle of the ultra-low volume sprayer is horizontally and upwardly inclined at an angle of 0-90 °.

4. The automatic spray mosquito eradication system for aedes disease media of claim 1 wherein the swivel base comprises: a rotary platform connected and driven by a rotary shaft of the motor and a power supply assembly for supplying power; the top of the rotating platform is provided with a containing groove for placing the ultra-low volume sprayer;

the power interface of the power supply assembly is inserted into the accommodating groove from the bottom of the rotary platform; the power plug of the ultra-low volume sprayer is arranged at the bottom of the power plug and is inserted into the accommodating groove to be correspondingly and electrically connected with the power interface.

5. The automatic spray mosquito eradication system for aedes disease medium of claim 4 wherein the top or side of the rotary platform is provided with a switch socket, a waterproof cover made of plastic material is sleeved outside the switch socket, and the waterproof cover is provided with perforations corresponding to the insertion holes of the switch socket.