CN113817595A

CN113817595A - Biological spore catches real-time supervision equipment based on thing networking

Info

Publication number: CN113817595A
Application number: CN202111059995.5A
Authority: CN
Inventors: 秦维彩; 陈盼阳; 陈晨
Original assignee: Nanjing Research Institute for Agricultural Mechanization Ministry of Agriculture
Current assignee: Nanjing Research Institute for Agricultural Mechanization Ministry of Agriculture
Priority date: 2021-09-10
Filing date: 2021-09-10
Publication date: 2021-12-21

Abstract

The utility model provides a biological spore catches real-time supervision equipment based on thing networking, includes the frame, the upper end of frame be equipped with solar energy electroplax, wind-force wind direction sensor, raspberry group and temperature and humidity sensor, the upper end of drain pan be equipped with the casing of rotation connection, driving motor's output be equipped with axis of rotation and extend to the shell inboard, the other end of axis of rotation be equipped with the polygon cylinder, the shell in be equipped with hollow rotating shaft, the drain pan in be equipped with vacuum pump and vacuum pump connection hollow rotating shaft. Wind direction and temperature and humidity sensor through raspberry group connection have reached the long-range purpose of obtaining field wind speed, wind direction, temperature, humidity data in real time, and driving motor drive polygon cylinder rotates certain angle every day for the spore that catches a whole day all on every face to the polygon cylinder, has reached the purpose that the spore that the elimination caught on the day produced the overlapping phenomenon with the spore that catches on the day before.

Description

Biological spore catches real-time supervision equipment based on thing networking

Technical Field

The invention relates to the technical field of biological spore capture, in particular to biological spore capture real-time monitoring equipment based on the Internet of things.

Background

In the process of agricultural disease control, the spore trap is an important tool for germ monitoring, is an instrument for detecting pathogenic spores in air and observing spores and pollen dust particles in a specific area at a fixed point, and provides reliable information for predicting and preventing disease prevalence and infection. Since the spore catcher is widely popularized and applied in the modern agricultural field, the occurrence frequency and scale of main diseases in agriculture are effectively controlled, the quality and benefit of agricultural production are obviously improved, the contribution to agricultural production is great, the existing spore catcher cannot acquire wind direction, wind speed, temperature and humidity data in the field in real time, the automation degree is not high, and the spore catcher continuously rotates a round roller by a clockwork spring, so that spores caught in the current day and spores caught in the previous day are overlapped.

Disclosure of Invention

The invention aims to solve the technical problems of acquiring field wind direction, wind speed, temperature and humidity data, automating equipment and preventing the phenomenon of overlapping with spores captured on the previous day, and provides biological spore capturing real-time monitoring equipment based on the Internet of things.

In order to solve the technical problems, the technical scheme provided by the invention is as follows:

a biological spore capturing real-time monitoring device based on the Internet of things comprises a frame, wherein a solar electric plate and a wind force and wind direction sensor are arranged at the upper end of the frame, a bottom shell is arranged at the bottom in the frame, a raspberry group and a temperature and humidity sensor are arranged on one side of the bottom shell, a shell body connected in a rotating mode is arranged at the upper end of the bottom shell, the shell body comprises a shell with a detachable top cover and a detachable top cover lower end, a driving motor is arranged in the top cover, the output end of the driving motor is provided with a rotating shaft, the rotating shaft extends to the inner side of the shell, a polygonal roller is arranged at the other end of the rotating shaft, a wind vane is arranged on one side of the shell body, an air inlet narrow pipe is arranged on the other side of the shell body, a hollow rotating shaft and a bearing are arranged in the shell, a bearing is arranged on the outer side of the hollow rotating shaft, and the outer side of the bearing is fixedly connected with the outer side of the hollow rotating shaft, the bottom shell is internally provided with a vacuum pump which is connected with a hollow rotating shaft.

After adopting the structure, the invention has the following advantages: wind direction, temperature humidity transducer on the spore seizure instrument are connected through raspberry group, have reached the long-range purpose of obtaining field wind speed, wind direction, temperature, humidity data in real time, and driving motor drive polygon cylinder rotates certain angle every day for the spore that catches whole day all on every face to the polygon cylinder, has reached the purpose that the spore that the elimination was caught on the day produced overlapping phenomenon with the spore that the day caught in the past.

As the improvement, the polygon cylinder be hexagon cylinder structure, every face of polygon cylinder on even be equipped with the glass piece of paining vaseline, the polygon cylinder is hexagon cylinder structure, is equipped with 6 faces, can let driving motor drive hexagon cylinder structure rotate 60 every day for the spore that a whole day was caught all on every face to the polygon cylinder, reached and eliminated the spore that this day was caught and the spore that the day was caught before and produced the purpose of overlapping phenomenon, can realize the effect that 6 days detected simultaneously.

As an improvement, the solar panel is electrically connected with the raspberry pi, the temperature and humidity sensor, the wind power and wind direction sensor and the driving motor.

As an improvement, the outer side of the bottom shell is provided with supporting legs, and the supporting legs are fixedly connected with the frame through bolts.

As an improvement, the top cover and the shell are fixedly connected through bolts.

Drawings

Fig. 1 is a schematic structural diagram of biological spore capture real-time monitoring equipment based on the internet of things.

FIG. 2 is a front view of a biological spore capture real-time monitoring device wind vane based on the Internet of things.

FIG. 3 is a schematic diagram of the internal structure of a polygonal roller of the biological spore trapping real-time monitoring device based on the Internet of things.

Fig. 4 is a schematic structural diagram of an air inlet narrow pipe for real-time monitoring of biological spore capture based on the internet of things.

Fig. 5 is an internal schematic diagram of a bottom case of the biological spore capture real-time monitoring device based on the internet of things.

As shown in the figure: 1. a frame; 2. a solar panel; 3. a wind direction sensor; 4. a bottom case; 4.1, a vacuum pump; 4.2, supporting legs; 5. a raspberry pie; 6. a temperature and humidity sensor; 7. a housing; 7.1, a top cover; 7.2, a shell; 7.3, air inlet narrow pipes; 7.4, a hollow rotating shaft; 8. a drive motor; 8.1, a rotating shaft; 9. a polygonal drum; 10. a bearing; 10.1, a support column; 11. a wind vane.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

With reference to the accompanying drawings 1-5, a biological spore capturing real-time monitoring device based on the internet of things comprises a frame 1, a solar electric plate 2 and a wind force and wind direction sensor 3 are arranged at the upper end of the frame 1, a bottom shell 4 is arranged at the bottom of the frame 1, a raspberry group 5 and a temperature and humidity sensor 6 are arranged on one side of the bottom shell 4, a shell 7 connected in a rotating mode is arranged at the upper end of the bottom shell 4, the shell 7 comprises a top cover 7.1 and a shell 7.2 with the lower end detachable from the top cover 7.1, a driving motor 8 is arranged in the top cover 7.1, a rotating shaft 8.1 is arranged at the output end of the driving motor 8, the rotating shaft 8.1 extends to the inner side of the shell 7.2, a polygonal roller 9 is arranged at the other end of the rotating shaft 8.1, a wind direction indicator 11 is arranged on one side of the shell 7, an air inlet narrow pipe 7.3 is arranged on the other side of the shell 7, a hollow rotating shaft 7.4 is arranged in the shell 7.2 and the hollow rotating shaft 7.4 extends to the inner side of the shell 7.2, the outside of hollow rotating shaft 7.4 be equipped with bearing 10, the inboard fixed connection hollow rotating shaft 7.4 outside fixed connection shell 7.2 of bearing 10, drain pan 4 in be equipped with vacuum pump 4.1 and vacuum pump 4.1 connection hollow rotating shaft 7.4.

Polygonal cylinder 9 be hexagon cylinder structure, polygonal cylinder 9 every face on even be equipped with the glass piece of paining the vaseline. When the invention is implemented specifically, the polygonal roller 9 can also be a quadrilateral roller, the raspberry pi 5 is an ARM-based microcomputer mainboard and can be externally connected with a computer, an L298N driver is arranged in the raspberry pi 5 and serves as a driving plate module of a driving motor, and the driving motor 8 is controlled remotely to drive the hexagonal roller to rotate 60 degrees every day or the quadrilateral roller to rotate 180 degrees every day, so that the hexagonal roller rotates a certain angle every day. With the face of the polygonal drum 9 facing the narrow inlet duct 7.3.

Solar energy electroplax 2 with raspberry group 5, temperature and humidity sensor 6, wind-force wind direction sensor 3 and driving motor 8 electricity be connected, raspberry group 4 connects wind-force wind direction, temperature and humidity sensor 6 and wind-force wind direction sensor 3, has reached the long-range purpose of obtaining field wind speed, wind direction, temperature, humidity data in real time. The solar panel 2 provides power for the raspberry pi 5, the temperature and humidity sensor 6, the wind direction sensor 3, the driving motor 8 and the vacuum pump 4.1.

The outside of drain pan 4 be equipped with supporting leg 4.2, supporting leg 4.2 through bolt fixed connection frame 1, vacuum pump 4.1 work is evacuated, supporting leg 4.2 plays to support drain pan 4 fixed.

The top cover 7.1 and the shell 7.2 are fixedly connected through bolts.

The working principle of the invention is as follows: the shell relies on wind-force to blow the wind vane, make the shell rotatory under the effect of the drive of wind vane and bearing, the slot is to the wind direction, be convenient for catch the spore, the L298N driver of raspberry group is connected, the polygon cylinder relies on computer telnet raspberry group, control L298N driver, make driving motor work, it rotates the angle that sets up to drive the polygon cylinder, the vacuum pump relies on the solar cell panel power supply, constantly follow and take out the air with 10L/min, make the spore inhale from air inlet narrow tube department, the glass piece of vaseline is paintd to the striking on the polygon cylinder. When the spores are captured every day, the raspberry pie controls, the driving motor works to drive the polygonal roller to rotate by a set angle, and if the polygonal roller 9 rotates by 60 degrees in a hexagonal roller structure; the polygonal roller 9 is a quadrangular roller which rotates 180 degrees, one surface of the polygonal roller faces the air inlet narrow pipe, and the phenomenon that spores captured on the same day are overlapped with spores captured on the previous day is avoided.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. The utility model provides a biological spore catches real-time supervision equipment based on thing networking, includes frame (1), its characterized in that, the upper end of frame (1) be equipped with solar energy electroplax (2) and wind-force wind direction sensor (3), frame (1) in the bottom be equipped with drain pan (4), one side of drain pan (4) be equipped with raspberry group (5) and temperature and humidity sensor (6), the upper end of drain pan (4) be equipped with shell (7) of rotation connection, shell (7) include top cap (7.1) and top cap (7.1) lower extreme detachable shell (7.2), top cap (7.1) in be equipped with driving motor (8), the output of driving motor (8) be equipped with axis of rotation (8.1) and axis of rotation (8.1) extend to shell (7.2) inboard, the other end of axis of rotation (8.1) be equipped with polygon cylinder (9), one side of casing (7) be equipped with wind vane (11), the opposite side of casing (7) be equipped with air inlet narrow tube (7.3), shell (7.2) in be equipped with hollow pivot (7.4) and hollow pivot (7.4) extend to the inboard of shell (7.2), the outside of hollow pivot (7.4) be equipped with bearing (10), inboard fixed connection hollow pivot (7.4) outside fixed connection shell (7.2) of bearing (10), drain pan (4) in be equipped with vacuum pump (4.1) and vacuum pump (4.1) connection hollow pivot (7.4).

2. The biological spore capture real-time monitoring device based on the internet of things of claim 1, wherein: polygonal cylinder (9) be hexagon cylinder structure, polygonal cylinder (9) every face on even be equipped with the glass piece of paining vaseline.

3. The biological spore capture real-time monitoring device based on the internet of things of claim 1, wherein: the solar panel (2) is electrically connected with the raspberry pie (5), the temperature and humidity sensor (6), the wind power and wind direction sensor (3) and the driving motor (8).

4. The biological spore capture real-time monitoring device based on the internet of things of claim 1, wherein: the outer side of the bottom shell (4) is provided with a supporting leg (4.2), and the supporting leg (4.2) is fixedly connected with the frame (1) through a bolt.

5. The biological spore capture real-time monitoring device based on the internet of things of claim 1, wherein: the top cover (7.1) is fixedly connected with the shell (7.2) through bolts.