CN111034591A

CN111034591A - Agricultural intelligent irrigation platform and method

Info

Publication number: CN111034591A
Application number: CN201911337166.1A
Authority: CN
Inventors: 张洪雷; 王晓磊; 申博宇; 李树勇
Original assignee: Aerospace Hi Tech Holding Group Co Ltd
Current assignee: Aerospace Hi Tech Holding Group Co Ltd
Priority date: 2019-12-23
Filing date: 2019-12-23
Publication date: 2020-04-21

Abstract

The invention discloses an agricultural intelligent irrigation platform, which comprises: user login module, after confirming user information and the authority that has, allow the login platform, the platform read farm controller upload to the server in with the sensor parameter that the user corresponds, farm controller control includes water pump and water pump solenoid valve, illumination intensity sensor, air humidity transducer, air temperature sensor and earth temperature and humidity sensor, according to different planting crops and the temperature, humidity and the illumination intensity parameter self-adaptation matching irrigation model of this day, water and electric degree of use when farm irrigation are gathered simultaneously to the platform after the irrigation, the expense that generates the degree of use is uploaded the server and in order to inform the user. Compared with the prior art, the off-site irrigation system can realize off-site irrigation of users and realize better and more economical water and electricity cost control.

Description

Agricultural intelligent irrigation platform and method

Technical Field

The invention relates to the field of agricultural control of Internet of things, in particular to a platform and a method for agricultural intelligent irrigation.

Background

At present, agricultural irrigation refers to irrigation of water, different irrigation modes such as a field irrigation canal method, a drip irrigation method and a spraying method exist, the traditional irrigation method cannot effectively solve the problems of water pollution and insufficient water resources at present, meanwhile, the traditional irrigation method focuses on water supplement, trace elements and CO2 elements for crop growth are not considered, an additional CO2 supplement machine is needed in greenhouse planting, some CO2 in the traditional agricultural application is produced by a combustion method, and some CO2 is synthesized chemically, and the traditional method not only pollutes the environment, but also increases the production cost. Meanwhile, with the progress of society and the development of scientific technology, especially the development of communication industry, the rhythm of life of people is promoted and accelerated, the convenience, the rapidness and the high efficiency become necessary conditions for modern life, work and study, especially for water use or irrigation in rural areas and remote mountainous areas, if modern science and technology and communication are used, energy and water are saved, time and labor are saved, a water pipe unit is facilitated to monitor water for users in real time, remote control is facilitated, and the water fee payment is facilitated for users by means of communication tools such as mobile phones. For users, the water fee payment usually takes half a day to one day to queue up at the water pipe station for payment, the water fee can not be quantified during irrigation, and people can leave after the irrigation is finished, so that the time waste of people is caused, the workload of staff at the water pipe station is increased, and the working efficiency is reduced; and because the remote topography of some districts is complicated for to the staff of water pipe station, it has increased the difficulty to reach to the water gauge station and read meter, and it is difficult to reduce work efficiency still to waste time and energy, and long-range meter reading is difficult, can not real time monitoring user's water condition, causes the water waste, uses inconveniently.

Some farmland irrigation mainly adopts manual work to well house operation equipment, and the charging mode adopts manual recording irrigation time or charges according to power consumption, and the irrigation mode is flooded to heavy water, and equipment is simple and easy rough, does not have good equipment protection performance, wastes water, electricity and manpower, causes a large amount of wastes of resources.

Therefore, the problem to be solved is to find an irrigation method which can realize remote, high-efficiency and water and electricity saving.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. To this end, the invention discloses an agricultural intelligent irrigation platform, comprising: user login module, after confirming user information and the authority that has, allow the login platform, the platform read farm controller upload to the server in with the sensor parameter that the user corresponds, farm controller control includes water pump and water pump solenoid valve, illumination intensity sensor, air humidity transducer, air temperature sensor and earth temperature and humidity sensor, according to different planting crops and the temperature, humidity and the illumination intensity parameter self-adaptation matching irrigation model of this day, water and electric degree of use when farm irrigation are gathered simultaneously to the platform after the irrigation, the expense that generates the degree of use is uploaded the server and in order to inform the user.

Still further, the platform further comprises: the platform passes through wireless communication mode and farm host computer connection, the instruction of far-end user is accepted to the farm controller, the solenoid valve switch is controlled through gateway, relay to the hardware of farm controller to send the order with the help of the farm host computer and realize the irrigation instruction, finally form actual irrigation action.

Further, the platform for simultaneously collecting water and electricity usage during farm irrigation further comprises: the total water quantity of the farm site through the greenhouse irrigation system is finely calculated through a flow sensor, when water flow passes through the flow sensor, a data line can generate continuous pulses, water consumption is evaluated through the pulses, an upper limit of the irrigation water quantity is set in advance when a user executes an irrigation task through a platform, and an irrigation flow and irrigation starting time are determined according to the actual requirement of the determined irrigation model.

Furthermore, the gateway collects and uploads command data of the upper computer and realizes receiving and sending of information.

Still further, the farm site further comprises: and the image acquisition unit is used for regularly photographing crops and uploading the photos to the server after each irrigation task is executed.

The invention also discloses an agricultural intelligent irrigation method, a user logs in an agricultural intelligent irrigation platform through a login module, after verifying the user information and the authority thereof, allowing to log in a platform, wherein the platform calls the farm information corresponding to the user from a database server, and reading sensor parameters corresponding to the user uploaded to the server by the farm controller, wherein the farm controller comprises a water pump, a water pump electromagnetic valve, an illumination intensity sensor, an air humidity sensor, an air temperature sensor and a soil temperature and humidity sensor, adaptively matching an irrigation model in an irrigation model server according to different planted crops and the temperature, humidity and illumination intensity parameters of the current day, simultaneously collecting the water and electricity consumption during farm irrigation, and after the irrigation is finished, generating the cost of the usage degree, uploading the cost to the server and informing a user.

Further, the simultaneous collection of water and electricity consumption for farm irrigation further comprises: when a user selects to frequently see irrigation water and electricity consumption information, the total water consumption of a farm site through a greenhouse irrigation system is finely calculated through a flow sensor, when water flow passes through the flow sensor, a data path generates continuous pulses, the water consumption is evaluated through the pulses, an upper limit of the irrigation water quantity is set in advance when the user executes an irrigation task through a platform, and an irrigation flow and an irrigation starting time are determined according to the actual requirement of the determined irrigation model.

Furthermore, when a user needs to acquire farm site data, the farm site acquires and uploads command data of the upper computer through the gateway and receives and sends information.

Still further, the farm site further comprises: the crops are photographed regularly, and the photos are uploaded to a server after the irrigation tasks are executed each time.

Compared with the prior art, beneficial effect does: according to the intelligent agricultural irrigation system, the remote irrigation platform is arranged, a user logs in the intelligent agricultural irrigation platform through the login module, after user information and the authority of the user are verified, the login platform is allowed, the platform calls farm information corresponding to the user from the database server, sensor parameters corresponding to the user and uploaded to the server by a farm controller are read, the irrigation model is matched in the irrigation model server in a self-adaptive mode according to different planted crops and temperature, humidity and illumination intensity parameters of the day, water and electricity consumption during farm irrigation is collected, and after irrigation is finished, cost of the consumption is generated and uploaded to the server and is reported to the user.

Drawings

The invention will be further understood from the following description in conjunction with the accompanying drawings. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the embodiments. In the drawings, like reference numerals designate corresponding parts throughout the different views.

FIG. 1 is a block diagram of the platform for agricultural intelligent irrigation of the present invention;

FIG. 2 is a flow chart of a method of agricultural intelligent irrigation of the present invention.

Detailed Description

Example one

A platform for agricultural intelligent irrigation as shown in fig. 1, said platform comprising: user login module, after confirming user information and the authority that has, allow the login platform, the platform read farm controller upload to the server in with the sensor parameter that the user corresponds, farm controller control includes water pump and water pump solenoid valve, illumination intensity sensor, air humidity transducer, air temperature sensor and earth temperature and humidity sensor, according to different planting crops and the temperature, humidity and the illumination intensity parameter self-adaptation matching irrigation model of this day, water and electric degree of use when farm irrigation are gathered simultaneously to the platform after the irrigation, the expense that generates the degree of use is uploaded the server and in order to inform the user.

Example two

As shown in fig. 2, the embodiment also discloses an agricultural intelligent irrigation method, wherein a user logs in an agricultural intelligent irrigation platform through a login module, after verifying the user information and the authority thereof, allowing to log in a platform, wherein the platform calls the farm information corresponding to the user from a database server, and reading sensor parameters corresponding to the user uploaded to the server by the farm controller, wherein the farm controller comprises a water pump, a water pump electromagnetic valve, an illumination intensity sensor, an air humidity sensor, an air temperature sensor and a soil temperature and humidity sensor, adaptively matching an irrigation model in an irrigation model server according to different planted crops and the temperature, humidity and illumination intensity parameters of the current day, simultaneously collecting the water and electricity consumption during farm irrigation, and after the irrigation is finished, generating the cost of the usage degree, uploading the cost to the server and informing a user.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

Although the invention has been described above with reference to various embodiments, it should be understood that many changes and modifications may be made without departing from the scope of the invention. It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intended to define the spirit and scope of this invention. The above examples are to be construed as merely illustrative and not limitative of the remainder of the disclosure. After reading the description of the invention, the skilled person can make various changes or modifications to the invention, and these equivalent changes and modifications also fall into the scope of the invention defined by the claims.

Claims

1. A platform for agricultural intelligent irrigation, the platform comprising: user login module, after confirming user information and the authority that has, allow the login platform, the platform read farm controller upload to the server in with the sensor parameter that the user corresponds, farm controller control includes water pump and water pump solenoid valve, illumination intensity sensor, air humidity transducer, air temperature sensor and earth temperature and humidity sensor, according to different planting crops and the temperature, humidity and the illumination intensity parameter self-adaptation matching irrigation model of this day, water and electric degree of use when farm irrigation are gathered simultaneously to the platform after the irrigation, the expense that generates the degree of use is uploaded the server and in order to inform the user.

2. The platform for agricultural intelligent irrigation of claim 1, wherein said platform further comprises: the platform passes through wireless communication mode and farm host computer connection, the instruction of far-end user is accepted to the farm controller, the solenoid valve switch is controlled through gateway, relay to the hardware of farm controller to send the order with the help of the farm host computer and realize the irrigation instruction, finally form actual irrigation action.

3. The agricultural intelligent irrigation platform of claim 2, wherein said platform for simultaneously harvesting water and electricity for farm irrigation further comprises: the total water quantity of the farm site through the greenhouse irrigation system is finely calculated through a flow sensor, when water flow passes through the flow sensor, a data line can generate continuous pulses, water consumption is evaluated through the pulses, an upper limit of the irrigation water quantity is set in advance when a user executes an irrigation task through a platform, and an irrigation flow and irrigation starting time are determined according to the actual requirement of the determined irrigation model.

4. The platform for agricultural intelligent irrigation according to claim 3, wherein the gateway collects and uploads upper computer command data and realizes information receiving and sending.

5. The agricultural intelligent irrigation platform of claim 4, wherein the farm site further comprises: and the image acquisition unit is used for regularly photographing crops and uploading the photos to the server after each irrigation task is executed.

6. An agricultural intelligent irrigation method is characterized in that a user logs in an agricultural intelligent irrigation platform through a login module, after verifying the user information and the authority thereof, allowing to log in a platform, wherein the platform calls the farm information corresponding to the user from a database server, and reading sensor parameters corresponding to the user uploaded to the server by the farm controller, wherein the farm controller comprises a water pump, a water pump electromagnetic valve, an illumination intensity sensor, an air humidity sensor, an air temperature sensor and a soil temperature and humidity sensor, adaptively matching an irrigation model in an irrigation model server according to different planted crops and the temperature, humidity and illumination intensity parameters of the current day, simultaneously collecting the water and electricity consumption during farm irrigation, and after the irrigation is finished, generating the cost of the usage degree, uploading the cost to the server and informing a user.

7. The method of agricultural intelligent irrigation of claim 6, wherein said platform further comprises: the platform passes through wireless communication mode and farm host computer connection, the instruction of far-end user is accepted to the farm controller, the solenoid valve switch is controlled through gateway, relay to the hardware of farm controller to send the order with the help of the farm host computer and realize the irrigation instruction, finally form actual irrigation action.

8. The method of claim 7, wherein said simultaneously collecting water and electricity usage for farm irrigation further comprises: when a user selects to frequently see irrigation water and electricity consumption information, the total water consumption of a farm site through a greenhouse irrigation system is finely calculated through a flow sensor, when water flow passes through the flow sensor, a data path generates continuous pulses, the water consumption is evaluated through the pulses, an upper limit of the irrigation water quantity is set in advance when the user executes an irrigation task through a platform, and an irrigation flow and an irrigation starting time are determined according to the actual requirement of the determined irrigation model.

9. The method for agricultural intelligent irrigation according to claim 8, wherein when a user needs to acquire farm site data, the farm site collects and uploads upper computer command data through the gateway and receives and sends information.

10. The method of agricultural intelligent irrigation of claim 9, wherein said farm site further comprises: the crops are photographed regularly, and the photos are uploaded to a server after the irrigation tasks are executed each time.