CN219088018U - Ecological agriculture irrigation system - Google Patents

Abstract

The utility model discloses an ecological agriculture water conservancy irrigation system, and relates to the technical field of water conservancy irrigation. The utility model comprises a control booster pump, a partition control mechanism, a data monitoring mechanism, a partition ground soil and a watering mechanism, wherein one side of a water outlet of the control booster pump is sequentially connected with a fertilizing mechanism, a diversion mechanism and a filtering mechanism, one side of the partition control mechanism is respectively provided with the data monitoring mechanism and the partition ground soil, and the watering mechanism is uniformly inserted on the upper side of the partition ground soil. According to the utility model, the soil condition and the air temperature are monitored in real time, the irrigation period is automatically regulated and controlled according to the types of crops, the monitoring camera is arranged, feedback information is provided for staff, the plant growth condition is conveniently known and adjustment is made, and the problems that the existing irrigation system is mostly regular irrigation, adjustment is difficult to be made in time when the environment changes, time and labor are wasted in manual adjustment, the efficiency is low, the irrigation system has errors, timely feedback cannot be obtained, and the growth of crops is affected are solved.

Description

Ecological agriculture irrigation system

Technical Field

The utility model belongs to the technical field of irrigation, and particularly relates to an ecological agriculture irrigation system.

Background

The irrigation system is a complete set of facilities of irrigation engineering, and consists of irrigation canal head engineering, water delivery, water distribution engineering, field irrigation engineering and the like, can realize automatic irrigation management of farmlands, reduces the labor intensity and achieves the effect of saving cost; the prior art publication CN 107484930U-an ecological agriculture irrigation system, is provided with a water storage pipe, a sewer pipe and a handle, after a water source flows out, the water source can automatically return to the original position under the cooperation of gears, so that the problems that the prior irrigation system can not achieve simple and rapid irrigation at any time, and needs multiple people to operate, wastes time and energy and waste water source are solved.

However, the following drawbacks still exist in practical use:

1. the existing ecological agriculture irrigation system is used for regularly irrigating crops, the growth of the crops is influenced by various factors, the irrigation system is difficult to realize automatic and dynamic management, manual monitoring and adjustment are needed, labor is consumed, the efficiency is low, and malnutrition or water loss and excessive conditions of the crops can be caused by negligence of staff;

2. the existing ecological agriculture irrigation system irrigates crops regularly, but after the irrigation system works for a period of time, information errors can occur, the information errors are not regulated for a long time, the growth of the crops is affected, and the farmland is divided into a plurality of areas, so that workers are difficult to know the growth conditions of the crops in each area in real time.

Disclosure of Invention

The utility model aims to provide an ecological agriculture irrigation system, which is provided with a real-time monitoring mechanism for monitoring soil conditions and air temperature, automatically regulating and controlling irrigation period according to crop types, and a monitoring camera for feeding back information to workers, so that the workers can know plant growth conditions and make adjustments conveniently, and the problems that the existing irrigation system is mainly used for regular irrigation, is difficult to make adjustments in time when the environment changes, is time-consuming and labor-consuming, has low efficiency, and can not obtain timely feedback and affects crop growth due to errors in the irrigation system are solved.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the utility model relates to an ecological agriculture irrigation system, which comprises a control booster pump, a partition control mechanism, a data monitoring mechanism, partition ground soil and an irrigation mechanism, wherein one side of a water outlet of the control booster pump is sequentially connected with a fertilizing mechanism, a diversion mechanism and a filtering mechanism, a water inlet of the control booster pump is connected with a water pipe of a reservoir, a water outlet of the filtering mechanism is connected with a main pipe, the tail end of the main pipe is uniformly connected with a branch pipe, the tail end of the branch pipe is connected with the partition control mechanism, one side of the partition control mechanism is respectively provided with the data monitoring mechanism and the partition ground soil, and the irrigation mechanism is uniformly inserted on the upper side of the partition ground soil.

Further, the partition control mechanism is composed of a control box, a manual interaction interface and a temperature monitoring component, wherein the manual interaction interface is connected to the end face of the box door of the control box, and the temperature monitoring component is connected to the end face of the box door of the control box through bolts.

Further, the top of the temperature monitoring component is connected with an external temperature detection rod, two sides of the corresponding position of the bottom of the control box are connected with branch pipes, and the branch pipes are uniformly connected with irrigation mechanisms above one side of the partitioned ground soil.

Further, the data monitoring mechanism is composed of a support column main body, a solar energy power storage plate, a monitoring camera, a signal transmission component and a soil monitoring component, wherein the solar energy power storage plate and the monitoring camera are connected to two sides of the top of the support column main body through bolts respectively, the signal transmission component is connected to the top end of the support column main body through bolts, and the soil monitoring component is connected to the bottom of the support column main body through bolts.

Further, the soil monitoring component comprises a column clamping piece, a data processing part, an information transmission line, a data analysis part and a soil monitoring probe, wherein the data processing part is fixed on one side of the column clamping piece, the information transmission line is connected on one side of the column clamping piece, the data analysis part is connected at the tail end of the information transmission line, and the soil monitoring probe is fixed at the bottom of the data analysis part.

Further, the irrigation mechanism consists of an irrigation water outlet pipe, an irrigation rotary nozzle, side support rods and ground fixing nails, wherein the top end of the irrigation water outlet pipe is connected with the irrigation rotary nozzle, the side support rods are connected with the two sides of the top of the irrigation water outlet pipe through bolts, and the ground fixing nails are inserted into the bottoms of the side support rods.

The utility model has the following beneficial effects:

1. an ecological agriculture irrigation system is provided with a monitoring mechanism, can monitor soil conditions and air temperature in real time, automatically regulate and control irrigation period according to crop types, realize automatic dynamic management, reduce human labor, and is higher in efficiency, and effectively protect the growth state of crops.

2. The ecological agriculture irrigation system is provided with a monitoring camera at the monitoring mechanism, and transmits monitoring information back to a mobile phone or a computer of a worker, so that the worker can know the growth condition of crops conveniently, and the partition control mechanism with information deviation can be adjusted, the plant growth environment is guaranteed, and the survival rate is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a water source treatment part of an ecological agriculture irrigation system;

FIG. 2 is a schematic diagram of the irrigation treatment section of the ecological agriculture irrigation system;

FIG. 3 is a schematic diagram of the structure of the connection of the data monitoring mechanism;

fig. 4 is a schematic structural view of the soil monitoring component.

In the drawings, the list of components represented by the various numbers is as follows:

1. controlling a booster pump; 101. a reservoir water pipe; 102. a main pipe; 103. a branch pipe; 2. a fertilization mechanism; 3. a diversion mechanism; 4. a filtering mechanism; 5. a partition control mechanism; 501. a control box; 502. a manual interaction interface; 503. a temperature monitoring component; 5031. an external temperature probe; 6. a data monitoring mechanism; 601. a support column main body; 602. a solar energy storage panel; 603. monitoring a camera; 604. a signal transmission section; 605. a soil monitoring component; 6051. a post clip; 6052. a data processing part; 6053. an information transmission line; 6054. a data analysis part; 6055. a soil monitoring probe; 7. partitioning ground soil; 8. a watering mechanism; 801. watering a water outlet pipe; 802. watering the rotary spray head; 803. a side support bar; 804. and (5) fixing nails on the ground.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Referring to fig. 1, 2 and 4, the ecological agriculture irrigation system comprises a control booster pump 1, a fertilizing mechanism 2, a diversion mechanism 3, a filtering mechanism 4, a partition control mechanism 5, a data monitoring mechanism 6, partition ground soil 7 and a watering mechanism 8, wherein one side of a water outlet of the control booster pump 1 is sequentially connected with the fertilizing mechanism 2, the diversion mechanism 3 and the filtering mechanism 4, a water inlet of the control booster pump 1 is connected with a reservoir water pipe 101, a water outlet of the filtering mechanism 4 is connected with a main pipe 102, a branch pipe 103 is uniformly connected with the tail end of the main pipe 102, the tail end of the branch pipe 103 is connected with the partition control mechanism 5, one side of the partition control mechanism 5 is respectively provided with the data monitoring mechanism 6 and partition ground soil 7, the upper side of the partition ground soil 7 is uniformly inserted with the watering mechanism 8, the watering mechanism 8 is composed of a watering water outlet pipe 801, a watering rotary nozzle 802, side support rods 803 and ground fixing nails 804, the top end of the watering outlet pipe 801 is connected with side support rods 803, and the bottom of the side support rods 803 are inserted with the ground fixing nails 804.

When the ecological agriculture irrigation system is normally utilized for irrigation of crops, firstly, water in the reservoir enters the control booster pump 1 to be pressurized and is sequentially transmitted to the fertilization mechanism 2, the diversion mechanism 3 and the filtering mechanism 4, then enters the partition control mechanism 5, and is sprayed and irrigated by the irrigation mechanism 8, and the partition control mechanism 5 controls the irrigation period.

As shown in fig. 3, the control box 501 is bolted to a temperature monitoring component 503 on an end face of a box door, an external temperature detecting rod 5031 is connected to the top of the temperature monitoring component 503, branch pipes 103 are connected to two sides of a corresponding position of the bottom of the control box 501, a watering mechanism 8 is uniformly connected to the branch pipes 103 above one side of the partitioned ground soil 7, the data monitoring mechanism 6 is composed of a support column main body 601, a solar electric power storage plate 602, a monitoring camera 603, a signal transmission component 604 and a soil monitoring component 605, the two sides of the top of the support column main body 601 are respectively bolted to the solar electric power storage plate 602 and the monitoring camera 603, the top of the support column main body 601 is bolted to the signal transmission component 604, the bottom of the support column main body 601 is bolted to the soil monitoring component 605, the soil monitoring component 605 is composed of a column clamping piece 6051, a data processing part 6052, an information transmission line 6053, a data analysis part 6054 and a soil monitoring probe 6055, one side of the column clamping piece 6051 is fixedly provided with the data processing part 6052, the end of the information transmission line 6053 is connected to one side of the column clamping piece 6053, the end of the information transmission line 6053 is fixedly provided with the data analysis part 6055, and the bottom of the data analysis part 6055 is fixedly provided with the soil analysis part 6055.

When the soil or the air temperature environment changes, the external temperature detection rod 5031 detects the air temperature change, the soil monitoring probe 6055 monitors the change condition of the soil and sends information to the partition control mechanism 5 and staff, and the partition control mechanism 5 automatically regulates an irrigation system by analyzing data so as to realize dynamic management.

As shown in fig. 3, the partition control mechanism 5 is composed of a control box 501, a manual interaction interface 502 and a temperature monitoring component 503, where the control box 501 is connected with the manual interaction interface 502 at the end face of the box door.

When the information has deviation, a worker observes that the crop growth condition is problematic from the monitoring camera 603, the worker can remotely control, adjust the irrigation system, or go to the local area to perform detailed observation and adjust at the manual interaction interface 502.

The utility model has the specific application as follows: when the ecological agriculture irrigation system is normally utilized for irrigation of crops, firstly, water in a reservoir enters a control booster pump 1 to be boosted and is sequentially transmitted to a fertilizing mechanism 2, a diversion mechanism 3 and a filtering mechanism 4, then enters a partition control mechanism 5, and is sprayed and irrigated by an irrigation mechanism 8, and the partition control mechanism 5 controls the irrigation period; when the soil or the air temperature environment changes, the external temperature detection rod 5031 detects the air temperature change, the soil monitoring probe 6055 monitors the change condition of the soil and sends information to the partition control mechanism 5 and staff, and the partition control mechanism 5 automatically regulates an irrigation system by analyzing data so as to realize dynamic management; when the information has deviation, a worker observes that the crop growth condition is problematic from the monitoring camera 603, the worker can remotely control, adjust the irrigation system, or go to the local area to perform detailed observation and adjust at the manual interaction interface 502.

The foregoing is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present utility model.

Claims (6)

1. The utility model provides an ecological agriculture irrigation system, includes control booster pump (1), subregion control mechanism (5), data monitoring mechanism (6), subregion ground soil (7) and watering mechanism (8), its characterized in that: the utility model discloses a water irrigation system, including control booster pump (1), fertilizer injection mechanism (2), guiding mechanism (3) and filtering mechanism (4) have been connected gradually to delivery port one side of control booster pump (1), the water inlet of control booster pump (1) links to each other with cistern water pipe (101), filtering mechanism (4) delivery port is connected with main pipe (102), main pipe (102) end evenly connected with branch pipe (103), branch pipe (103) end with partition control mechanism (5) link to each other, one side of partition control mechanism (5) is equipped with respectively data monitoring mechanism (6) with partition ground soil (7), partition ground soil (7) upside evenly peg graft have irrigation mechanism (8).

2. An ecological agriculture irrigation system according to claim 1, wherein: the partition control mechanism (5) is composed of a control box (501), a manual interaction interface (502) and a temperature monitoring component (503), wherein the manual interaction interface (502) is connected to the end face of a box door of the control box (501), and the temperature monitoring component (503) is connected to the end face of the control box (501) on one side of the box door through bolts.

3. An ecological agriculture irrigation system according to claim 2, wherein: the top of temperature monitoring part (503) is connected with outer temperature lever (5031), the both sides of the corresponding position of control box (501) bottom are connected with branch pipe (103), branch pipe (103) are in the top of subregion ground soil (7) one side evenly is connected with irrigation mechanism (8).

4. An ecological agriculture irrigation system according to claim 1, wherein: the data monitoring mechanism (6) is composed of a support column main body (601), a solar energy power storage plate (602), a monitoring camera (603), a signal transmission component (604) and a soil monitoring component (605), wherein the solar energy power storage plate (602) and the monitoring camera (603) are respectively connected to two sides of the top of the support column main body (601) through bolts, the signal transmission component (604) is connected to the top end of the support column main body (601) through bolts, and the soil monitoring component (605) is connected to the bottom of the support column main body (601) through bolts.

5. An ecological agriculture irrigation system as claimed in claim 4, wherein: soil monitoring part (605) are by post joint spare (6051), data processing part (6052), information transmission line (6053), data analysis part (6054) and soil monitoring probe (6055) are constituteed jointly, one side of post joint spare (6051) is fixed with data processing part (6052), one side of post joint spare (6051) is connected with information transmission line (6053), the end-to-end connection of information transmission line (6053) has data analysis part (6054), data analysis part (6054) bottom is fixed with soil monitoring probe (6055).

6. An ecological agriculture irrigation system according to claim 1, wherein: the irrigation mechanism (8) is composed of an irrigation water outlet pipe (801), an irrigation rotary nozzle (802), side support rods (803) and ground fixing nails (804), wherein the top end of the irrigation water outlet pipe (801) is connected with the irrigation rotary nozzle (802), the side support rods (803) are connected to two sides of the top of the irrigation water outlet pipe (801) through bolts, and the ground fixing nails (804) are inserted into the bottoms of the side support rods (803).

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