CN111096159A

CN111096159A - All-round control irrigation equipment of wisdom agricultural

Info

Publication number: CN111096159A
Application number: CN201911317261.5A
Authority: CN
Inventors: 郭晓艳; 金红靖; 许丹
Original assignee: Nanjing Niebo IOT Technology Co Ltd
Current assignee: Nanjing Niebo IOT Technology Co Ltd
Priority date: 2019-12-19
Filing date: 2019-12-19
Publication date: 2020-05-05

Abstract

The invention discloses an intelligent agricultural all-dimensional monitoring irrigation device which comprises a greenhouse, a first water tank, a first arched wall, a solar cell panel, a fixing box, a second water tank, a greenhouse door, an arched baffle, a second arched wall, a first liquid pump, a first infusion hose, a second liquid pump, a second infusion hose, a water delivery device, a supporting plate, a CPU, a controller, an LED lamp, a camera, a supporting rod, a supporting block, a U-shaped infusion tube, a first infusion tube, a second infusion tube, a spray head and a humidity sensor. The invention has the advantages of time saving, labor saving, uniform irrigation, high irrigation efficiency, high automation degree and convenience for monitoring and observing the conditions in the greenhouse; the use method is simple and convenient, the operation is convenient, the irrigation effect is good, and the water resource is saved.

Description

All-round control irrigation equipment of wisdom agricultural

Technical Field

The invention relates to the technical field of irrigation devices, in particular to an intelligent agricultural all-dimensional monitoring irrigation device.

Background

In the crop planting process, due to various factors such as uneven precipitation distribution, different soil texture and the like, artificial irrigation is often needed, and therefore an irrigation device is needed.

However, the existing irrigation device is time-consuming and labor-consuming, uneven in irrigation, low in irrigation efficiency and low in automation degree, and is inconvenient for monitoring and observing the conditions in the greenhouse; the use method is not simple and convenient, the irrigation effect is poor, the water resource is wasted, and the operation is inconvenient.

Therefore, the invention needs to provide a novel greenhouse, which is time-saving, labor-saving, uniform in irrigation, high in irrigation efficiency, high in automation degree and convenient for monitoring and observing the conditions in the greenhouse; the intelligent agricultural all-dimensional monitoring irrigation device has the advantages of simple and convenient use method, good irrigation effect, water resource saving and convenient operation

Disclosure of Invention

The invention aims to provide an intelligent agricultural all-dimensional monitoring irrigation device, which aims to solve the problems of time and labor waste, uneven irrigation, low irrigation efficiency, low automation degree and inconvenience in monitoring and observing the conditions in a greenhouse in the background technology; the use method is not simple and convenient, the irrigation effect is poor, the water resource is wasted, and the operation is inconvenient.

In order to realize the purpose, the invention provides the following technical scheme: an intelligent agricultural all-dimensional monitoring irrigation device comprises a greenhouse, a first water tank, a first arched wall body, a solar cell panel, a fixing box, a second water tank, a greenhouse door, an arched baffle, a second arched wall body, a first liquid pump, a first infusion hose, a second liquid pump, a second infusion hose, a water delivery device, a supporting plate, a CPU (Central processing Unit), a controller, an LED (light emitting diode) lamp, a camera, a supporting rod, a supporting block, a U-shaped infusion tube, a first infusion tube, a second infusion tube, a spray head, a humidity sensor, a constant humidity sensor, an on-off controller and a temperature sensor, wherein the greenhouse is arranged between the first arched wall body and the second arched wall body; the greenhouse is provided with a fixed box; the fixed box is provided with a solar cell panel; the first arched wall body and the second arched wall body are respectively and fixedly connected with arched baffles; the two arched baffles are respectively provided with a greenhouse door; a first water tank is arranged on the side wall of the greenhouse; a second water tank is arranged on the other side wall of the greenhouse; a second liquid pump is arranged in the second water tank; the output end of the second liquid pump is connected with a second infusion hose; the second infusion hose is fixedly connected with a water delivery device; a first liquid pump is arranged in the first water tank; the first liquid pump is connected with a first transfusion hose; the first infusion hose and the second infusion hose are fixedly connected with the water delivery device; a support plate is arranged on the inner wall of the first arched wall body; the support plate is provided with a CPU; the controller and the supporting rod are arranged in the greenhouse; the support rod is fixedly connected with an LED lamp; the side wall of the supporting rod is fixedly connected with a supporting block; the supporting block is provided with a camera.

Preferably, a storage battery is arranged in the fixing box; the storage battery is electrically connected with the solar cell panel; the camera is electrically connected with the storage battery; generating electricity by utilizing solar energy; and energy is saved.

Preferably, the water delivery device comprises a U-shaped infusion tube, a first infusion tube, a second infusion tube and a spray head; a plurality of U-shaped infusion tubes are arranged on the first infusion tube; the other ends of the U-shaped infusion tubes are fixedly connected with second infusion tubes; a plurality of spray heads are respectively arranged on the plurality of U-shaped infusion tubes; the irrigation efficiency is higher.

Preferably, a plurality of U-shaped infusion tubes are uniformly arranged on the first infusion tube; a plurality of spray heads are uniformly arranged on the plurality of U-shaped infusion tubes; the irrigation is more uniform.

Preferably, the controller is provided with a constant humidity sensor, a power-on and power-off controller and a temperature sensor; the controller is connected with the storage battery; the controller is electrically connected with the CPU; the camera is electrically connected with the CPU; the first liquid pump and the second liquid pump are respectively electrically connected with the storage battery; the first liquid pump and the second liquid pump are respectively electrically connected with the controller; conveniently monitor the inside irrigation condition of big-arch shelter.

Preferably, the first arched wall body and the second arched wall body are made of concrete; the greenhouse is firmer.

Preferably, the first infusion hose and the second infusion hose are made of rubber; can be bent freely.

A use method of an intelligent agricultural all-dimensional monitoring irrigation device comprises the following steps: the method comprises the following steps:

s1: firstly, transmitting light energy received by a solar panel to a storage battery; converting the storage battery into electric energy; providing electric energy for the first liquid pump, the second liquid pump, the controller, the camera and the CPU;

s2: firstly, setting humidity parameters suitable for crops in the greenhouse through a constant humidity sensor, a controller and a humidity sensor; when the soil humidity in the greenhouse is higher than a preset parameter, the humidity sensor feeds back a signal to the controller; the controller receives the information; the first liquid pump and the second liquid pump send commands to enable the first liquid pump and the second liquid pump to convey water in the first water tank and the second water tank to the water conveying device; irrigating crops;

s3: finally, observing the irrigation condition of crops in the greenhouse according to the CPU and the camera; then according to the illumination intensity in the greenhouse; the LED lamp is selectively turned on or off.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the intelligent agricultural all-dimensional monitoring irrigation device, a first water tank is arranged on the side wall of a greenhouse; a second water tank is arranged on the other side wall of the greenhouse; a second liquid pump is arranged in the second water tank; the output end of the second liquid pump is connected with a second infusion hose; the second transfusion hose is fixedly connected with a water delivery device; a first liquid pump is arranged in the first water tank; the first liquid pump is connected with a first transfusion hose; the first infusion hose and the second infusion hose are fixedly connected with the water delivery device; using a second liquid pump and a first liquid pump to pump water in the first water tank and the second water tank into the water delivery device; irrigating crops in the greenhouse; manual water digging is omitted for irrigation; time and labor are saved; and the irrigation mode is to use a plurality of shower nozzles to carry out fountain irrigation to it, avoids the impact irrigation, and the irrigation effect is better, leads to crops to wash out and waste water resource.

2. The intelligent agricultural all-dimensional monitoring irrigation device comprises a U-shaped infusion tube, a first infusion tube, a second infusion tube and a spray head; a plurality of U-shaped infusion tubes are arranged on the first infusion tube; the other end of the U-shaped infusion tube is fixedly connected with a second infusion tube; a plurality of nozzles are respectively arranged on the U-shaped infusion tube; the crops are irrigated by using the plurality of U-shaped liquid conveying pipes and the plurality of spray heads, so that the irrigation efficiency is high; a plurality of U-shaped infusion tubes are uniformly arranged on the first infusion tube; a plurality of spray heads are uniformly arranged on the U-shaped infusion tube; the spray head and the U-shaped infusion tube are uniformly arranged; the irrigation is more uniform.

3. The intelligent agricultural all-dimensional monitoring irrigation device is characterized in that a controller is provided with a constant humidity sensor, a power-on and power-off controller and a temperature sensor; the controller is connected with the storage battery; the controller is electrically connected with the CPU; the camera is electrically connected with the CPU; the first liquid pump and the second liquid pump are respectively electrically connected with the storage battery; the first liquid pump and the second liquid pump are respectively electrically connected with the controller; the humidity parameters suitable for crops in the greenhouse are set through the constant humidity sensor, the controller and the humidity sensor; when the soil humidity in the greenhouse is higher than a preset parameter, the humidity sensor feeds back a signal to the controller; the controller receives the information; the first liquid pump and the second liquid pump send commands to enable the first liquid pump and the second liquid pump to convey water in the first water tank and the second water tank to the water conveying device; irrigating crops; observing the irrigation condition of crops in the greenhouse according to the CPU and the camera; the worker only needs to feed back the image inside the greenhouse to the CPU through the camera; and monitoring and observing the conditions inside the greenhouse.

4. The intelligent agricultural all-dimensional monitoring irrigation device is characterized in that a controller is provided with a constant humidity sensor, a power-on and power-off controller and a temperature sensor; the controller is connected with the storage battery; the controller is electrically connected with the CPU; the camera is electrically connected with the CPU; the first liquid pump and the second liquid pump are respectively electrically connected with the storage battery; the first liquid pump and the second liquid pump are respectively electrically connected with the controller; the humidity parameters suitable for crops in the greenhouse are set through the constant humidity sensor, the controller and the humidity sensor; when the soil humidity in the greenhouse is higher than a preset parameter, the humidity sensor feeds back a signal to the controller; the controller receives the information; the first liquid pump and the second liquid pump send commands to enable the first liquid pump and the second liquid pump to convey water in the first water tank and the second water tank to the water conveying device; irrigating crops; the degree of automation is relatively high.

5. A use method of an intelligent agricultural all-dimensional monitoring irrigation device comprises the following steps: the method is characterized in that: the method comprises the following steps: s1: firstly, transmitting light energy received by a solar panel to a storage battery; converting the storage battery into electric energy; providing electric energy for the first liquid pump, the second liquid pump, the controller, the camera and the CPU; s2: firstly, setting humidity parameters suitable for crops in the greenhouse through a constant humidity sensor, a controller and a humidity sensor; when the soil humidity in the greenhouse is higher than a preset parameter, the humidity sensor feeds back a signal to the controller; the controller receives the information; the first liquid pump and the second liquid pump send commands to enable the first liquid pump and the second liquid pump to convey water in the first water tank and the second water tank to the water conveying device; irrigating crops; s3: finally, observing the irrigation condition of crops in the greenhouse according to the CPU and the camera; then according to the illumination intensity in the greenhouse; selectively turning on or off the LED lamp; the use method is simple and convenient, and the operation is convenient.

Drawings

FIG. 1 is a schematic view of an intelligent agricultural omni-directional monitoring irrigation device according to the present invention;

FIG. 2 is a schematic view of a part of the intelligent agricultural omni-directional monitoring irrigation device according to the present invention;

FIG. 3 is a schematic view of a part of the intelligent agricultural omni-directional monitoring irrigation device according to the present invention;

FIG. 4 is a schematic view of the internal structure of a greenhouse of the intelligent agricultural all-directional monitoring irrigation device;

FIG. 5 is a schematic structural view of a water delivery device of the intelligent agricultural all-directional monitoring irrigation device;

FIG. 6 is a schematic diagram of a controller of the intelligent agricultural all-directional monitoring irrigation device;

fig. 7 is a schematic diagram of the system connection of the original components of the intelligent agricultural all-directional monitoring irrigation device.

In the figure: 1-greenhouse; 2-a first water tank; 3-a first arcuate wall; 4-a solar panel; 5-fixing the box; 6-a second water tank; 7-a greenhouse door; 8-an arched baffle; 9-a second arcuate wall; 10-a first liquid pump; 11-a first infusion hose; 12-a second liquid pump; 13-a second infusion hose; 14-a water delivery device; 15-a support plate; 16-a CPU; 17-a controller; 18-LED lamps; 19-a camera; 20-a support bar; 21-a support block; 141-U shaped infusion tube; 142-a first infusion tube; 143-a second infusion tube; 144-a spray head; 171-a humidity sensor; 172-constant humidity sensor; 173-on/off controller; 174-temperature sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution of an intelligent agricultural omni-directional monitoring irrigation device: the greenhouse comprises a greenhouse 1, a first water tank 2, a first arched wall 3, a solar panel 4, a fixing box 5, a second water tank 6, a greenhouse door 7, an arched baffle 8, a second arched wall 9, a first liquid pump 10, a first infusion hose 11, a second liquid pump 12, a second infusion hose 13, a water delivery device 14, a support plate 15, a CPU16, a controller 17, an LED lamp 18, a camera 19, a support rod 20, a support block 21, a U-shaped infusion tube 141, a first infusion tube 142, a second infusion tube 143, a spray head 144, a humidity sensor 171, a constant humidity sensor 172, a power-on and power-off controller 173 and a temperature sensor 174, wherein the greenhouse 1 is arranged between the first arched wall 3 and the second arched wall 9; the greenhouse 1 is provided with a fixed box 5; the fixed box 5 is provided with a solar cell panel 4; the first arched wall 3 and the second arched wall 9 are fixedly connected with arched baffles 8 respectively; the two arched baffles 8 are respectively provided with a greenhouse door 7; a first water tank 2 is arranged on the side wall of the greenhouse 1; the other side wall of the greenhouse 1 is provided with a second water tank 6; a second liquid pump 12 is arranged inside the second water tank 6; the output end of the second liquid pump 12 is connected with a second infusion hose 13; the second infusion hose 13 is fixedly connected with a water delivery device 14; a first liquid pump 10 is arranged in the first water tank 2; the first liquid pump 10 is connected with a first transfusion hose 11; the first infusion hose 11 and the second infusion hose 13 are fixedly connected with a water delivery device 14; a support plate 15 is arranged on the inner wall of the first arched wall 3; the supporting plate 15 is provided with a CPU 16; the controller 17 and the support rods 20 are arranged in the greenhouse 1; the support rod 20 is fixedly connected with an LED lamp 18; the side wall of the support rod 20 is fixedly connected with a support block 21; the supporting block 21 is provided with a camera 19.

In this embodiment, a storage battery is disposed inside the fixing box 5; the storage battery is electrically connected with the solar cell panel 4; the camera 19 is electrically connected with the storage battery; generating electricity by utilizing solar energy; and energy is saved.

In this embodiment, the water delivery device 14 includes a U-shaped infusion tube 141, a first infusion tube 142, a second infusion tube 143, and a spray head 144; a plurality of U-shaped infusion tubes 141 are arranged on the first infusion tube 142; the other ends of the U-shaped infusion tubes 141 are fixedly connected with second infusion tubes 143; a plurality of spray heads 144 are respectively arranged on the plurality of U-shaped infusion tubes 141; the irrigation efficiency is higher.

In this embodiment, a plurality of U-shaped infusion tubes 141 are uniformly disposed on the first infusion tube 142; a plurality of spray heads 144 are uniformly arranged on the plurality of U-shaped infusion tubes 141; the irrigation is more uniform.

In this embodiment, the controller 17 is provided with a constant humidity sensor 171, a humidity sensor 172, a power on/off controller 173 and a temperature sensor 174; the controller 17 is connected with the storage battery; the controller 17 is electrically connected with the CPU 16; the camera 19 is electrically connected with the CPU 16; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with a storage battery; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with the controller 17; conveniently monitor the inside irrigation condition of big-arch shelter.

In this embodiment, the first arched wall 3 and the second arched wall 9 are made of concrete; the greenhouse is firmer.

In this embodiment, the first infusion hose 11 and the second infusion hose 13 are made of rubber; can be bent freely.

A use method of an intelligent agricultural all-dimensional monitoring irrigation device comprises the following steps: the method is characterized in that: the method comprises the following steps:

s1: firstly, the light energy received by the solar panel 4 is transmitted to a storage battery; converting the storage battery into electric energy; supplying power to the first liquid pump 10, the second liquid pump 12, the controller 17, the camera 19, and the CPU 16;

s2: firstly, setting humidity parameters suitable for crops in the greenhouse 1 through a constant humidity sensor 172, a controller 17 and a humidity sensor 171; when the soil humidity in the greenhouse 1 is higher than the preset parameter, the humidity sensor 171 will feed back a signal to the controller 17; the controller 17 receives the information; commands are sent to the first liquid pump 10 and the second liquid pump 12, so that the first liquid pump 10 and the second liquid pump 12 can convey the water in the first water tank 2 and the second water tank 6 to the water conveying device 14; irrigating crops;

s3: finally, observing the irrigation condition of crops in the greenhouse 1 according to the CPU16 and the camera 19; then according to the illumination intensity inside the greenhouse 1; the LED lamp 18 is selectively turned on or off.

The working principle is as follows: according to the intelligent agricultural all-dimensional monitoring irrigation device, a first water tank 2 is arranged on the side wall of a greenhouse 1; a second water tank 6 is arranged on the other side wall of the greenhouse 1; a second liquid pump 12 is arranged in the second water tank 6; the output end of the second liquid pump 12 is connected with a second infusion hose 13; the second infusion hose 13 is fixedly connected with a water delivery device 14; a first liquid pump 10 is arranged inside the first water tank 2; the first liquid pump 10 is connected with a first transfusion hose 11; the first infusion hose 11 and the second infusion hose 13 are fixedly connected with a water delivery device 14; the water inside the first and

second water tanks

2 and 6 is drawn into the water delivery device 14 using the second and first

liquid pumps

12 and 10; irrigating crops in the greenhouse 1; manual water digging is omitted for irrigation; time and labor are saved; and the irrigation mode is to use a plurality of spray nozzles 144 to carry out spray irrigation on the crops, so that impact irrigation is avoided, crops are damaged by impact, and water resources are wasted. In the intelligent agricultural all-directional monitoring irrigation device, the water delivery device 14 comprises a U-shaped infusion tube 141, a first infusion tube 142, a second infusion tube 143 and a spray head 144; a plurality of U-shaped infusion tubes 141 are arranged on the first infusion tube 142; a second infusion tube 143 is fixedly connected to the other end of the U-shaped infusion tube 141; a plurality of nozzles 144 are respectively arranged on the U-shaped infusion tube 141; the crops are irrigated by using the plurality of U-shaped infusion tubes 141 and the plurality of spray heads 144, so that the irrigation efficiency is high; a plurality of U-shaped infusion tubes 141 are uniformly arranged on the first infusion tube 142; a plurality of spray heads 144 are uniformly arranged on the U-shaped infusion tube 141; the spray head 144 and the U-shaped infusion tube 141 are uniformly arranged; the irrigation is more uniform. In the intelligent agricultural all-directional monitoring irrigation device, a controller 17 is provided with a constant humidity sensor 171, a humidity sensor 172, a power-on and power-off controller 173 and a temperature sensor 174; the controller 17 is connected with the storage battery; the controller 17 is electrically connected with the CPU 16; the camera 19 is electrically connected with the CPU 16; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with a storage battery; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with the controller 17; the humidity sensor 172, the controller 17 and the humidity sensor 171 are set to be suitable for the humidity parameters of crops in the greenhouse 1; when the soil humidity in the greenhouse 1 is higher than the preset parameter, the humidity sensor 171 will feed back a signal to the controller 17; the controller 17 receives the information; commands are sent to the first liquid pump 10 and the second liquid pump 12, so that the first liquid pump 10 and the second liquid pump 12 can convey the water in the first water tank 2 and the second water tank 6 to the water conveying device 14; irrigating crops; observing the irrigation condition of crops in the greenhouse 1 according to the CPU16 and the camera 19; the worker only needs to feed back the image inside the greenhouse to the CPU16 through the camera 19; the condition inside the greenhouse 1 is monitored and observed. In the intelligent agricultural all-directional monitoring irrigation device, a controller 17 is provided with a constant humidity sensor 171, a humidity sensor 172, a power-on and power-off controller 173 and a temperature sensor 174; the controller 17 is connected with the storage battery; the controller 17 is electrically connected with the CPU 16; the camera 19 is electrically connected with the CPU 16; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with the storage battery; the first liquid pump 10 and the second liquid pump 12 are respectively electrically connected with the controller 17; the humidity sensor 172, the controller 17 and the humidity sensor 171 are set to be suitable for the humidity parameters of crops in the greenhouse 1; when the soil humidity in the greenhouse 1 is higher than the preset parameter, the humidity sensor 171 will feed back a signal to the controller 17; the controller 17 receives the information; commands are sent to the first liquid pump 10 and the second liquid pump 12, so that the first liquid pump 10 and the second liquid pump 12 can convey the water in the first water tank 2 and the second water tank 6 to the water conveying device 14; irrigating crops; the degree of automation is relatively high. A use method of an intelligent agricultural all-dimensional monitoring irrigation device comprises the following steps: the method is characterized in that: the method comprises the following steps: s1: firstly, the light energy received by the solar panel 4 is transmitted to a storage battery; converting the storage battery into electric energy; supplying power to the first liquid pump 10, the second liquid pump 12, the controller 17, the camera 19, and the CPU 16; s2: firstly, setting humidity parameters suitable for crops in the greenhouse 1 through a constant humidity sensor 172, a controller 17 and a humidity sensor 171; when the soil humidity in the greenhouse 1 is higher than the preset parameter, the humidity sensor 171 will feed back a signal to the controller 17; the controller 17 receives the information; commands are sent to the first liquid pump 10 and the second liquid pump 12, so that the first liquid pump 10 and the second liquid pump 12 can convey the water in the first water tank 2 and the second water tank 6 to the water conveying device 14; irrigating crops; s3: finally, observing the irrigation condition of crops in the greenhouse 1 according to the CPU16 and the camera 19; then according to the illumination intensity inside the greenhouse 1; selectively turning on or off the LED lights 18; the use method is simple and convenient, and the operation is convenient.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. The utility model provides an all-round control irrigation equipment of wisdom agricultural, its characterized in that: the method is characterized in that: comprises a greenhouse (1), a first water tank (2), a first arched wall body (3), a solar cell panel (4), a fixing box (5), a second water tank (6), a greenhouse door (7), an arched baffle (8), a second arched wall body (9), a first liquid pump (10), a first infusion hose (11), a second liquid pump (12), a second infusion hose (13), a water delivery device (14), a support plate (15), a CPU (16), a controller (17), an LED lamp (18), a camera (19), a support rod (20), a support block (21), a U-shaped infusion tube (141), a first infusion tube (142), a second infusion tube (143), a spray head (144), a humidity sensor (171), a constant humidity sensor (172), an on-off controller (173) and a temperature sensor (174), a greenhouse (1) is arranged between the first arched wall (3) and the second arched wall (9); the greenhouse (1) is provided with a fixed box (5); the fixed box (5) is provided with a solar panel (4); the first arched wall (3) and the second arched wall (9) are fixedly connected with arched baffles (8) respectively; the two arched baffles (8) are respectively provided with a greenhouse door (7); a first water tank (2) is arranged on the side wall of the greenhouse (1); a second water tank (6) is arranged on the other side wall of the greenhouse (1); a second liquid pump (12) is arranged in the second water tank (6); the output end of the second liquid pump (12) is connected with a second infusion hose (13); the second transfusion hose (13) is fixedly connected with a water transfusion device (14); a first liquid pump (10) is arranged in the first water tank (2); the first liquid pump (10) is connected with a first transfusion hose (11); the first infusion hose (11) and the second infusion hose (13) are fixedly connected with a water delivery device (14); a support plate (15) is arranged on the inner wall of the first arched wall body (3); a CPU (16) is arranged on the supporting plate (15); a controller (17) and a support rod (20) are arranged in the greenhouse (1); the support rod (20) is fixedly connected with an LED lamp (18); the side wall of the support rod (20) is fixedly connected with a support block (21); the supporting block (21) is provided with a camera (19).

2. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 1, wherein: a storage battery is arranged in the fixed box (5); the storage battery is electrically connected with the solar cell panel (4); the camera (19) is electrically connected with the storage battery.

3. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 1, wherein: the water delivery device (14) comprises a U-shaped infusion tube (141), a first infusion tube (142), a second infusion tube (143) and a spray head (144); a plurality of U-shaped infusion tubes (141) are arranged on the first infusion tube (142); the other ends of the U-shaped infusion tubes (141) are fixedly connected with second infusion tubes (143); a plurality of spray heads (144) are respectively arranged on the U-shaped infusion tubes (141).

4. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 3, wherein: a plurality of U-shaped infusion tubes (141) are uniformly arranged on the first infusion tube (142); a plurality of spray heads (144) are uniformly arranged on the U-shaped infusion tubes (141).

5. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 1, wherein: the controller (17) is provided with a constant humidity sensor (171), a humidity sensor (172), a power on/off controller (173) and a temperature sensor (174); the controller (17) is connected with the storage battery; the controller (17) is electrically connected with the CPU (16); the camera (19) is electrically connected with the CPU (16); the first liquid pump (10) and the second liquid pump (12) are respectively electrically connected with the storage battery; the first liquid pump (10) and the second liquid pump (12) are respectively electrically connected with the controller (17).

6. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 1, wherein: the first arched wall body (3) and the second arched wall body (9) are made of concrete.

7. The intelligent agricultural all-directional monitoring irrigation device as claimed in claim 1, wherein: the first infusion hose (11) and the second infusion hose (13) are made of rubber.

8. A use method of an intelligent agricultural all-dimensional monitoring irrigation device comprises the following steps: the method is characterized in that: the method comprises the following steps:

s1: firstly, the light energy received by the solar panel (4) is transmitted to a storage battery; converting the storage battery into electric energy; the electric energy is supplied to the first liquid pump (10), the second liquid pump (12), the controller (17), the camera (19) and the CPU (16);

s2: firstly, setting humidity parameters suitable for crops in the greenhouse (1) through a constant humidity sensor (172), a controller (17) and a humidity sensor (171); when the soil humidity in the greenhouse (1) is higher than a preset parameter, the humidity sensor (171) feeds back a signal to the controller (17); the controller (17) receives the information; the water delivery device sends commands to the first liquid pump (10) and the second liquid pump (12) to enable the first liquid pump (10) and the second liquid pump (12) to deliver water in the first water tank (2) and the second water tank (6) to the water delivery device (14); irrigating crops;

s3: finally, the irrigation condition of crops in the greenhouse (1) is observed according to the CPU (16) and the camera (19); then according to the illumination intensity inside the greenhouse (1); the LED lamp (18) is selectively turned on or off.