CN216700213U - Multi-well irrigation system with water-electricity ratio correlation - Google Patents

Abstract

The utility model discloses a water-electricity ratio associated multiwell irrigation system, which comprises a standard well and at least one associated well, wherein the standard well is provided with a first water pump, the first water pump is provided with a flow meter and a first ammeter, the system also comprises a first microprocessor, the first microprocessor is provided with a flow meter interface and a first ammeter interface, the first microprocessor is connected with the flow meter through the flow meter interface to obtain water consumption data of the first microprocessor, the first microprocessor is connected with the first ammeter through the first ammeter interface to obtain electricity consumption data of the first microprocessor, and the first microprocessor calculates the proportion K of the water consumption data and the electricity consumption data after obtaining the water consumption data and the electricity consumption data; the first microprocessor is also connected with a first communication module, and the first microprocessor sends the proportion K through the first communication module; the method obtains the proportion K of the water consumption data and the power consumption data of the first water pump for pumping water of the standard well, and the proportion K is used for conversion of the water consumption data and the power consumption data of the second water pump of the associated well, thereby being beneficial to simplifying a metering system of the associated well.

Description

Multi-well irrigation system with water-electricity ratio correlation

Technical Field

The utility model relates to the technical field of motor-pumped well irrigation, in particular to a multi-motor-pumped well irrigation system with water-electricity proportion correlation.

Background

Agricultural production is a major problem related to the national civilization, rainwater is less in the north of China, farmland irrigation is one of main means for ensuring the harvest of crops, the farmland irrigation mainly utilizes river water sources or underground water sources, most of the farmland irrigation mainly utilizes motor-pumped wells for irrigation in underground well irrigation areas, and the motor-pumped wells (PumPing wells) are wells for PumPing water by utilizing a first water pump driven by a motor; aiming at the requirement of large-area irrigation, a plurality of motor-pumped wells are required to be established in an irrigation area, and underground water is pumped for irrigation of crops.

Because the underground water levels in the dry period and the rich period are different, the proportional relation between the electricity cost and the water cost consumed by the water pump is greatly changed; therefore, in the prior art, each motor-pumped well is provided with a water pump, each water pump is provided with an ammeter and is used for calculating the electric charge of the water pump, and each water pump is provided with a flowmeter and is used for calculating the water charge of the water pump. Finally, the cost of pumping irrigation is obtained by adding the two.

Therefore, the prior art has the defect that the water pump of each motor-pumped well needs to be provided with an electric meter and a flow meter, so that the structure of a metering system of the water pump is complex.

SUMMERY OF THE UTILITY MODEL

In view of at least one of the drawbacks of the prior art, it is an object of the present invention to provide a hydropower rate correlated multiple well irrigation system for obtaining a ratio K of water consumption data and power consumption data for pumping by a standard well first water pump, the ratio K being used for conversion of water consumption data and power consumption data for a correlated well second water pump, which helps to simplify the metering system of the correlated well.

In order to achieve the purpose, the utility model adopts the following technical scheme: a multiwell irrigation system with water-electricity proportion correlation comprises a standard well and at least one correlation well, wherein the standard well is provided with a first water pump, a flow meter is connected to a pipeline of the first water pump in series, the first water pump is also provided with a first electricity meter, the multiwell irrigation system further comprises a first microprocessor, the first microprocessor is connected with the first water pump through a first water pump control circuit to control the first water pump to work, the first microprocessor is provided with a flow meter interface, the first microprocessor is connected with the flow meter through the flow meter interface to obtain water consumption data of the first microprocessor, the first microprocessor is also provided with a first electricity meter interface, the first microprocessor is connected with the first electricity meter through the first electricity meter interface to obtain electricity consumption data of the first microprocessor, and the first microprocessor calculates the proportion K after obtaining the water consumption data and the electricity consumption data; the first microprocessor is also connected with a first communication module, and the first microprocessor sends the proportion K of the water consumption data and the power consumption data through the first communication module;

the associated well is provided with a second water pump which is provided with a second ammeter, and the associated well further comprises a second microprocessor which is connected with the second water pump through a second water pump control circuit to control the second water pump to work;

the second microprocessor is also provided with a second ammeter interface, the second microprocessor is connected with the second ammeter through the second ammeter interface to acquire power consumption data of the second microprocessor, and the second microprocessor calculates the water consumption data of the second water pump through the power consumption data and the proportion K of the second ammeter. The second microprocessor obtains the proportion K through the second communication module.

The first microprocessor is connected with the cloud platform through the first communication module and sends the proportion K of the water consumption data and the electricity consumption data to the cloud platform; and the second microprocessor is connected with the cloud platform through the second communication module to obtain the proportion K.

And the second communication module and the first communication module adopt RS485 communication modules.

The first microprocessor is also connected with a first RF interface, and the first microprocessor is connected with a first RF module through the first RF interface; the first RF module acquires an instruction of the RF card and then sends the instruction to the first microprocessor, and the first microprocessor controls the first water pump to work;

the second microprocessor is also connected with a second RF interface, and the second microprocessor is connected with a second RF module through the second RF interface.

The power supply module supplies power to the first microprocessor and the first communication module.

The multi-well irrigation system with the water-electricity ratio correlation has the advantages that the multi-well irrigation system with the water-electricity ratio correlation is used for obtaining the ratio K of water consumption data and electricity consumption data of the first water pump of the standard well for pumping water, the ratio K is used for converting the water consumption data and the electricity consumption data of the second water pump of the correlation well, and the multi-well irrigation system with the water-electricity ratio correlation is beneficial to simplifying the metering system of the correlation well.

Drawings

FIG. 1 is a block diagram of a circuit module according to the present invention;

FIG. 2 is a circuit diagram of a first microprocessor;

FIG. 3 is a circuit diagram of the periphery of the first microprocessor;

FIG. 4 is a circuit diagram of a clock module;

fig. 5 is a circuit diagram of a GPRS module;

FIG. 6 is a diagram of a first RF interface and its power supply circuit;

FIG. 7 is a circuit diagram of an RS485 module;

FIG. 8 is a circuit diagram of a power module;

FIG. 9 is a circuit diagram of an LCD interface;

FIG. 10 is a circuit diagram of a first memory;

FIG. 11 is a circuit diagram of a second memory;

fig. 12 is a circuit diagram of the first water pump control circuit.

Detailed Description

The utility model is described in further detail below with reference to the figures and specific examples.

As shown in fig. 1-12, a water-electricity ratio-associated multiwell irrigation system comprises a standard well and at least one associated well, wherein the standard well is provided with a first water pump, a flow meter is connected in series on a pipeline of the first water pump, the first water pump is also provided with a first electricity meter, the system further comprises a first microprocessor, the first microprocessor is connected with the first water pump through a first water pump control circuit to control the first water pump to work, the first microprocessor is provided with a flow meter interface, the first microprocessor is connected with the flow meter through the flow meter interface to obtain water consumption data of the first microprocessor, the first microprocessor is also provided with a first electricity meter interface, the first microprocessor is connected with the first electricity meter through the first electricity meter interface to obtain electricity consumption data of the first microprocessor, and the first microprocessor calculates the ratio K of the first microprocessor after obtaining the water consumption data and the electricity consumption data; the first microprocessor is also connected with a first communication module, and the first microprocessor sends the proportion K of the water consumption data and the power consumption data through the first communication module;

the associated well is provided with a second water pump which is provided with a second ammeter, and the associated well further comprises a second microprocessor which is connected with the second water pump through a second water pump control circuit to control the second water pump to work;

the second microprocessor is also provided with a second ammeter interface, the second microprocessor is connected with the second ammeter through the second ammeter interface to acquire power consumption data of the second microprocessor, and the second microprocessor calculates the water consumption data of the second water pump through the power consumption data and the proportion K of the second ammeter.

The first microprocessor is connected with the cloud platform through the first communication module and sends the proportion K of the water consumption data and the electricity consumption data to the cloud platform; and the second microprocessor is connected with the cloud platform through the second communication module to obtain the proportion K.

And the second communication module and the first communication module adopt RS485 communication modules.

The first microprocessor is also connected with a first RF interface, and the first microprocessor is connected with a first RF module through the first RF interface; the first RF module acquires an instruction of the RF card and then sends the instruction to the first microprocessor, and the first microprocessor controls the first water pump to work;

the second microprocessor is also connected with a second RF interface, and the second microprocessor is connected with a second RF module through the second RF interface.

The second RF radio frequency module is convenient for a user to irrigate by brushing the RF radio frequency card and using a second water pump of the associated well; and controlling a second water pump switch through the RF card.

The first water pump, the flow meter and the first electric meter are not shown in the attached drawings. The second water pump and the second electric meter are not shown in the attached drawings.

As shown in FIGS. 2 and 12, the first microprocessor is an STM32F103VET6 first microprocessor, the output end PD7 of the first microprocessor is connected with a first water pump control circuit, and the first water pump is controlled to work by the first water pump control circuit.

The first microprocessor is provided with a flow meter interface pin PD1, and the first microprocessor is connected with the flow meter through a pin PD1 to acquire water consumption data.

The first microprocessor is connected with a first electric meter through a first electric meter interface pin PD2 and a pin PC 3-pin PC7 to obtain the data of the electric quantity.

The first microprocessor calculates the proportion K of the water consumption data and the power consumption data after acquiring the water consumption data and the power consumption data; and sending the data to the cloud platform. K is water consumption data/electricity consumption data.

The cloud platform is connected with a plurality of associated wells, and the associated well only needs to set up the second ammeter, no longer needs to set up the flowmeter, when the user drew water through the second water pump of associated well, only needs to acquire its power consumption through its second ammeter, again with power consumption xK, can obtain the water consumption of corresponding associated well. And helps to simplify the metering system of the second water pump of the other associated well.

As shown in fig. 7, the first microprocessor is connected to a first communication module through a pin PB8, a pin PB10, and a pin PB11, and the first communication module is an RS485 first communication module.

The first microprocessor is also connected with a first RF interface, and the first microprocessor is connected with a first RF module through the first RF interface; the first RF module obtains an instruction of the RF card and then sends the instruction to the first microprocessor, and the first microprocessor controls the first water pump to work. The first RF module and the second RF module are not shown in the circuit diagram.

As shown in fig. 2 and 6, the first microprocessor is connected to a first RF interface through a pin PE 2-a pin PE4, and is connected to a first RF module through the first RF interface. A user sends an instruction to the first microprocessor through the RF card, and the first microprocessor controls the first water pump to work through the first water pump control circuit.

As shown in fig. 8, the system further includes a power module, and the power module supplies power to the first microprocessor and the first communication module.

As shown in fig. 2 and 9, the first microprocessor is further connected to a liquid crystal display interface through pin PE 9-pin PE14, and is connected to a liquid crystal display through the liquid crystal display interface, and displays water consumption data, power consumption data, a proportional relation between the water consumption data and the power consumption data through the liquid crystal display, and can also display alarm information.

The outlet of the first water pump is also provided with a pressure sensor, the pressure sensor is connected with a pin PC1 of the first microprocessor, the pressure sensor is used for acquiring the outlet pressure of the first water pump, when the outlet pressure of the first water pump is low, the first microprocessor sends an alarm signal to a manager through the GPRS module, and the GPRS module is shown in fig. 5. And the data can be sent to the cloud platform through an RS485 module. The standard well is further provided with a water level sensor, the first microprocessor is connected with the water level sensor through a pin PC0 and used for acquiring underground water level, and the underground water level is displayed through a display or sent to the cloud platform through an RS485 module.

As shown in fig. 10 to 11, the first microprocessor is further connected to a first memory for storing history records and a second memory for storing device parameter information.

The first microprocessor is also connected with a water level sensor, and the water level sensor is used for detecting the water level of the standard well and displaying or sending the water level to the cloud platform through the display.

As shown in fig. 4, the first microprocessor is further connected to a clock module, and the clock module provides time for the first microprocessor.

As shown in fig. 12, the water pump control circuit controls the operation of the water pump through a relay.

Finally, it is noted that: the above-mentioned embodiments are only examples of the present invention, and it is a matter of course that those skilled in the art can make modifications and variations to the present invention, and it is considered that the present invention is protected by the modifications and variations if they are within the scope of the claims of the present invention and their equivalents.

Claims (5)

1. A multiwell irrigation system with water-electricity ratio correlation is characterized by comprising a standard well and at least one correlation well, wherein the standard well is provided with a first water pump, a flow meter is connected to a pipeline of the first water pump in series, the first water pump is also provided with a first electric meter, the multiwell irrigation system also comprises a first microprocessor, the first microprocessor is connected with the first water pump through a first water pump control circuit to control the first water pump to work, the first microprocessor is provided with a flow meter interface, the first microprocessor is connected with the flow meter through the flow meter interface to acquire water consumption data of the first microprocessor, the first microprocessor is also provided with a first electric meter interface, the first microprocessor is connected with the first electric meter through the first electric meter interface to acquire power consumption data of the first microprocessor, and the first microprocessor calculates the ratio K after acquiring the water consumption data and the power consumption data; the first microprocessor is also connected with a first communication module, and the first microprocessor sends the proportion K of the water consumption data and the power consumption data through the first communication module;

the associated well is provided with a second water pump which is provided with a second ammeter, and the associated well further comprises a second microprocessor which is connected with the second water pump through a second water pump control circuit to control the second water pump to work;

the second microprocessor is also provided with a second ammeter interface, the second microprocessor is connected with the second ammeter through the second ammeter interface to acquire power consumption data of the second microprocessor, and the second microprocessor calculates the water consumption data of the second water pump through the power consumption data and the proportion K of the second ammeter.

2. A hydroelectric proportion-related multiwell irrigation system as claimed in claim 1, wherein: the first microprocessor is connected with the cloud platform through the first communication module and sends the proportion K of the water consumption data and the electricity consumption data to the cloud platform; and the second microprocessor is connected with the cloud platform through the second communication module to obtain the proportion K.

3. A hydroelectric proportion-related multiwell irrigation system as claimed in claim 2, wherein: and the second communication module and the first communication module adopt RS485 communication modules.

4. A hydroelectric proportion-related multiwell irrigation system as claimed in claim 1, wherein: the first microprocessor is also connected with a first RF interface, and the first microprocessor is connected with a first RF module through the first RF interface; the first RF module acquires an instruction of the RF card and then sends the instruction to the first microprocessor, and the first microprocessor controls the first water pump to work;

the second microprocessor is also connected with a second RF interface, and the second microprocessor is connected with a second RF module through the second RF interface.

5. The multiple well irrigation system with water-electricity ratio correlation of claim 1, wherein: the power supply module supplies power to the first microprocessor and the first communication module.

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