KR102669711B1 - Flow check water pipe system - Google Patents

Abstract

The present invention relates to a flow check water system, and more specifically, to provide efficient water management and distribution through flow check, and to reduce ground gouging when supplying water to rice fields through joint pipes and discharge pipes. It's about the water system.

Description

Flow check water pipe system}

The present invention relates to a flow check water system, and more specifically, to provide efficient water management and distribution through flow check, and to reduce ground gouging when supplying water to rice fields through joint pipes and discharge pipes. It's about the water system.

Generally, sewage generated from industrial sites or homes. In order to flow wastewater or chemical water to a designated purification facility or to irrigate rainwater or agricultural and industrial water, etc., concrete pipes such as hume pipes, bench plume pipes, U-type plume pipes, VR pipes, water pipes, perforated pipes, etc., or plastic pipes such as PE are used. These pipes are used as drain pipes to form waterways.

In addition, it is used to construct drain pipes or water pipes for the purpose of supplying or draining agricultural water to farmland.

In particular, concrete drain pipes and water pipes are widely used in rural areas, and concrete branch pipes with a circular or square cross-section are connected to the side walls or bottom of the concrete drain pipes and water pipes.

Water is supplied to farmland through the branch pipe, or water from the farmland is discharged into a water pipe. Alternatively, a drain pipe according to the farmland is installed to form a branch pipe in the drain pipe, and water from the farmland is discharged through the branch pipe of the drain pipe.

In relation to this, there is utility model document 1 as a structure for controlling the supply, discharge, and blocking of water.

The above utility model document 1 relates to a gate that controls the amount of agricultural water and has a water supply function. Specifically, it not only can easily supply water needed for crop growth to rice fields, but also provides selective opening and closing means by providing individual opening and closing means. This relates to a gate that enables the supply of water and can be easily installed in an existing waterway. Since both ends of the opening and closing plate can be raised and lowered in a balanced manner, the opening and closing plate is unsafe between the flow paths of the water pipe. It is provided in one posture, and the opening and closing plate can be raised and lowered by forward and reverse rotation of the rotary lever, so the worker does not have to manually raise and lower the opening and closing plate. This is a document about a structure that provides the effect.

The utility model document 1 is a structure installed in a water pipe (drain pipe) to control the flow of water in the water pipe (drain pipe). It is a structure that allows control of one direction of water flow, and is a structure in which the water pipe (drain pipe) is connected. There is a problem that is limited to only .

In other words, in the direction where the water pipe (drain pipe) is connected, it is a structure that blocks all of the water, or blocks or opens only part of it. To control the flow in the direction where the water pipe (drain pipe) is not connected, an additional water pipe (drain pipe) is connected. There is a problem that needs to be addressed.

As a document to solve this problem, there is Patent Document 1.

Patent Document 1 above relates to an agricultural drainage device. It is easy to open and close and fine-tune the drainage or water intake amount in agricultural waterways using a handle, and has remarkable durability through frequent use. In particular, it is installed on one side of the agricultural waterway depending on the direction of water flow. This relates to an agricultural drainage device that allows for common installation and use on both left and right sides of a waterway due to the variable installation structure of the vertically installed water sill, and is easy to install and use not only in agricultural waterways but also in water banks of general rice field ridges.

Patent Document 1 is a configuration in which water flows in through a water outlet, and the opening/closing door is controlled using an opening/closing handle to control the amount of inflowing water and open/close the door.

Patent Document 1 solves the problem of Utility Model Document 1, but Patent Document 1 has a coupling structure between an opening and closing handle and an opening and closing door, and is configured to move the opening and closing door to the left and right on the coupling axis using the opening and closing handle. In this configuration, a long hole is formed in the opening/closing handle to change the position of the joint movement axis between the opening/closing handle and the opening/closing door, making it easy to move the left/right position of the opening/closing door.

In particular, the traditional water management system relies on manual operation and lacks accuracy in flow and drainage control.

This causes problems such as water waste, unbalanced water distribution, and reduced crop yields.

Additionally, cleaning and maintenance are difficult, and real-time data for efficient water management is lacking.

That is, the conventional irrigation system relies heavily on manual operation, which makes precise control of water difficult and may result in unnecessary water waste.

Additionally, because the flow of water could not be controlled effectively, the land could easily be dug up and the soil eroded due to the high flow rate.

Additionally, existing pipelines and irrigation facilities were difficult to access for cleaning and maintenance, which could reduce the efficiency and lifespan of the system in the long term.

Additionally, the lack of accurate water usage measurement and monitoring made it difficult to efficiently manage water resources and establish an optimized irrigation plan.

(Utility Model Document 1) Korea Public Utility Model Publication No. 20-2014-0003589 Korean Patent Publication No. 10-1025254

Therefore, the present invention was devised to solve the above conventional problems,

The purpose of the present invention is to increase the efficiency of water use by providing sophisticated flow control and monitoring functions.

In other words, it provides accurate water usage data by providing an ultrasonic flow meter and optimizes water flow through automatic or manual control.

Another object of the present invention is to facilitate installation and maintenance of pipes by configuring a joint and a discharge pipe, to reduce digging, and to increase the stability of the connection between the joint and discharge pipe by configuring a flange.

Another purpose of the present invention is to configure a water supply spigot to enable accurate water supply at a location desired by the user.

In order to achieve the problem that the present invention seeks to solve,

The flow rate check water pipe system 1000 according to an embodiment of the present invention,

A water pipe 100 attached to the water channel wall 50 to control the flow and supply amount of water by controlling the opening and closing of the water through the lever 110,

A joint pipe (200) connected to the water supply pipe to control the flow rate of water,

A first flange portion 300 formed between the fitting pipe and the flow meter to firmly maintain the connection between the fitting pipe and the flow meter,

A flow meter 400 for measuring the flow rate of water supplied through the joint pipe and outputting the measured flow rate information or sending it to an external terminal 2000,

A second flange portion 500 formed between the flow meter and the discharge pipe to firmly maintain the connection between the flow meter and the discharge pipe,

The problem of the present invention is solved by being configured to include a discharge pipe 600 connected to the second flange portion and discharging water supplied through the joint pipe.

The flow check flow system of the present invention provides the following effects.

First, it provides sophisticated flow control and monitoring functions to increase water use efficiency.

In other words, it provides accurate water usage data by providing an ultrasonic flow meter and provides the effect of optimizing the flow of water through automatic or manual control.

Second, by configuring a joint and a discharge pipe, installation and maintenance of the pipe is facilitated, reducing digging, and by configuring a flange, it provides the effect of increasing the stability of the connection between the joint and the discharge pipe.

Third, by configuring the water supply spigot, it provides the effect of enabling accurate water supply at the user's desired location.

In other words, it solves existing problems by enabling accurate flow measurement and control, easy installation and maintenance, and sustainable use of water resources.

Figure 1 is an overall configuration diagram of a flow check water system according to an embodiment of the present invention.
Figures 2 and 3 are diagrams showing the overall configuration of the flow check water system according to an embodiment of the present invention as seen from different angles.
Figure 4 is an application example of the flow check water system according to an embodiment of the present invention.
Figure 5 is a remote monitoring configuration diagram of a flow rate check water system according to an embodiment of the present invention.
Figure 6 is an example screen of a flow rate check water system according to an embodiment of the present invention.
Figure 7 is an example report of the flow check water system according to an embodiment of the present invention.
Figure 8 is a prediction example of a flow rate check water system according to an embodiment of the present invention.

The following merely illustrates the principles of the invention. Therefore, one skilled in the art will be able to invent various devices that embody the principles of the present invention and are included within the spirit and scope of the present invention, although not explicitly described or shown herein.

In addition, all conditional terms and examples listed herein are, in principle, expressly intended only for the purpose of enabling the concept of the invention to be understood, and should be understood not as limiting to the examples and states specifically listed as such. do.

The flow rate check water pipe system 1000 according to an embodiment of the present invention,

A water pipe 100 attached to the water channel wall 50 to control the flow and supply amount of water by controlling the opening and closing of the water through the lever 110,

A joint pipe (200) connected to the water supply pipe to control the flow rate of water,

A first flange portion 300 formed between the fitting pipe and the flow meter to firmly maintain the connection between the fitting pipe and the flow meter,

A flow meter 400 for measuring the flow rate of water supplied through the joint pipe and outputting the measured flow rate information or sending it to an external terminal 2000,

A second flange portion 500 formed between the flow meter and the discharge pipe to firmly maintain the connection between the flow meter and the discharge pipe,

It is characterized by including a discharge pipe 600 connected to the second flange portion and discharging water supplied through the joint pipe.

At this time, the flow meter is characterized by being installed in a clamping manner between the first flange portion 300 and the second flange portion 500.

At this time, the joint pipe 200 and the discharge pipe 600 are,

It is characterized by including a stopper (lid) installed at the end of the straight section to facilitate cleaning.

Hereinafter, the flow rate check water stop system according to the present invention will be described in detail through examples.

Figure 1 is an overall configuration diagram of a flow rate check water system according to an embodiment of the present invention.

Figures 2 and 3 are diagrams showing the overall configuration of the flow check water system according to an embodiment of the present invention as seen from different angles.

Figure 4 is an application example of the flow check water system according to an embodiment of the present invention.

Figure 5 is a remote monitoring configuration diagram of a flow rate check water system according to an embodiment of the present invention.

Figure 6 is an example screen of a flow rate check water system according to an embodiment of the present invention.

Figure 7 is an example report of the flow check water system according to an embodiment of the present invention.

Figure 8 is a prediction example of a flow rate check water system according to an embodiment of the present invention.

As shown in Figures 1 to 8, the flow rate check water system 1000 of the present invention,

A water pipe 100 attached to the water channel wall 50 to control the flow and supply amount of water by controlling the opening and closing of the water through the lever 110,

A joint pipe (200) connected to the water supply pipe to control the flow rate of water,

A first flange portion 300 formed between the fitting pipe and the flow meter to firmly maintain the connection between the fitting pipe and the flow meter,

A flow meter 400 for measuring the flow rate of water supplied through the joint pipe and outputting the measured flow rate information or sending it to an external terminal 2000,

A second flange portion 500 formed between the flow meter and the discharge pipe to firmly maintain the connection between the flow meter and the discharge pipe,

It is characterized by including a discharge pipe 600 connected to the second flange portion and discharging water supplied through the joint pipe.

To be specific, as shown in FIG. 4, the water supply spigot 100 is attached to the water channel wall 50 and controls the opening and closing of the water through the lever 110 to control the flow and flow of water. It performs the function of controlling the supply amount.

That is, the water tap includes a lever 110 that the user can easily operate, and the lever is connected to the open/close valve of the water tap, and the user can adjust the open/close state of the valve by rotating the lever. .

For example, it can be configured as 'Handle-type water supply control device', which is Republic of Korea Patent No. 10-1744152 applied for and registered by the inventor of the present invention.

Additionally, the valve opens or closes depending on the rotation of the lever, which controls the amount of water flowing into the waterway. When the valve is fully open, the maximum amount of water can pass through, and when it is completely closed, the water flow stops completely. blocked.

Additionally, the user can precisely control the flow of water by finely adjusting the lever, which is useful for adjusting the amount of water supplied according to the moisture needs of crops or supplying a certain amount of water for a specific time.

To elaborate, water is a precious resource in agriculture and irrigation systems, and precise control of water supply points prevents water waste and enables efficient water use.

And, user-friendly operation: manual lever operation can provide users with an intuitive control method while minimizing technical complexity, can be applied to various sizes and types of waterways, and can be easily installed and adjusted due to the simplicity of lever operation. do.

In addition, the fitting pipe 200 is connected to the water supply pipe and performs a function of controlling the flow rate of water.

Specifically, as shown in Figures 1 to 3, the joint pipe has a structure bent at a curved angle, which can increase the space efficiency of the pipe layout, which is especially useful in situations where a water supply line must be installed in a limited space. do.

If space is not limited, a straight design is also possible.

Also, even if it is not at the above curved angle, a rapid stopper that can reduce the flow rate can be used inside.

In addition, the structure of the joint pipe plays a role in somewhat slowing down the flow rate of water passing through it. This smoothes the flow of water, regulates the pressure within the pipe line, and prevents excessive digging when water is discharged to farmland. It provides an effect.

Meanwhile, a lid 210 for cleaning is installed at the end of the straight section of the joint pipe.

Through the lid, users can easily remove foreign substances or deposits accumulated inside the pipe, and maintain the efficiency and lifespan of the pipe through regular cleaning.

In addition, the fitting pipe is connected to the water supply outlet, so that the flow rate of water adjusted at the water supply outlet is transmitted through the pipe. This connection ensures smooth distribution and control of water.

Through the above configuration, the following functions are provided.

As for space efficiency, the curved angle configuration enables space saving and flexible pipe layout configuration.

As flow rate and pressure management, by regulating the flow rate, it manages the pressure in the pipeline and provides a smooth flow of water.

For ease of maintenance, the lid installation configuration makes cleaning and maintenance work simple.

In addition, the first flange portion 300 is formed between the fitting pipe and the flow meter, and functions to firmly maintain the connection between the fitting pipe and the flow meter.

In other words, the main purpose of flanges is to provide a stable, leak-free connection within a pipeline.

In addition, the first flange portion is generally made of steel, iron, stainless steel, or other durable materials, and is provided in various sizes and thicknesses, and an appropriate flange is selected depending on the size and pressure rating of the pipe.

And, it is formed between the fitting pipe and the flow meter, and is tightened together using bolts and nuts, so that the pipeline is connected firmly and stably.

In addition, a gasket or sealing material is usually inserted into the first flange portion to prevent water leakage at the connection area, and the sealing material is a material with excellent resistance to pressure, temperature, and chemicals.

In addition, connection through the first flange portion facilitates maintenance and pipeline inspection. For example, the pipe can be separated by unscrewing the first flange portion and reconnected after repair or replacement work.

In summary, flanges increase the strength and durability of the pipeline, maintain a stable connection even under high pressure or temperature conditions, and flanges used in conjunction with sealing materials ensure leak-free connections, improving the efficiency of the entire water system.

Additionally, the connection of the first flange portion facilitates maintenance and modification of the pipeline, and allows the pipeline to be easily adjusted or expanded as needed.

In addition, the flow meter 400 measures the flow rate of water supplied through the fitting pipe and performs the function of outputting the measured flow rate information or transmitting it to the external terminal 2000.

At this time, preferably, the flow meter is characterized by an ultrasonic type.

At this time, preferably, the flow meter is installed in a clamping manner between the first flange portion 300 and the second flange portion 500.

To be specific, an ultrasonic flow meter measures flow rate using the single-channel ultrasonic principle. This method determines the flow rate by measuring the difference in transmission time of ultrasonic signals that changes depending on the flow rate of the passing fluid.

And, the ultrasonic flow meter provides the following configuration and advantages.

First, high precision and low drift, the data obtained through correlation calculation of signal waveforms provides high precision, and low drift characteristics enable long-term stable measurements.

Second, as for interference prevention and stability, it can provide an interference prevention function and provides the advantage of being less affected by external noise or electromagnetic interference, thereby providing measurement accuracy and stability.

Third, adaptive signal amplitude and waveform analysis provides the signal amplitude adjustment function and advanced waveform analysis function that adapt to changes in conditions inside the pipe, providing the advantage of accurate measurement even in environments with scaling or sediment. do.

Fourth, as for data transmission, measured data can be transmitted in real time, allowing irrigation system managers or farmers to monitor water usage in real time.

In addition, the second flange portion 500 is formed between the flow meter and the discharge pipe and functions to firmly maintain the connection between the flow meter and the discharge pipe.

That is, it is located at the end of the ultrasonic flow meter to maintain the continuity of the pipeline and provide a stable connection, and the second flange portion serves to connect the flow meter and the discharge pipe 600.

Also, like the first flange part, it firmly maintains the connection between the flow meter and the discharge pipe, ensures smooth flow of fluid, and prevents leakage of the entire water system.

In addition, when maintenance or replacement of the flow meter is required, the second flange part can be easily separated and worked on, which simplifies the maintenance work of the water system and saves time.

Additionally, since it contains appropriate sealing materials, it is possible to maintain a leak-free connection.

In addition, the discharge pipe 600 is connected to the second flange portion and performs a function of discharging water supplied through the joint pipe.

Specifically, the discharge pipe 600 also adjusts the flow rate of water to reduce digging when supplying water to rice fields or other agricultural fields.

Specifically, the above purpose can be achieved by providing a curved structure, and as another configuration, a rapid prevention piece can be formed inside the discharge pipe to change the direction of water flow to naturally reduce the flow rate.

This has the effect of alleviating the shock when water touches the ground and reducing land erosion.

However, it is obvious that straight lines are possible when there are no space limitations.

In addition, the structure of the discharge pipe plays a role in controlling the flow rate of water, which allows water to spread smoothly over farmland, preventing soil erosion and ensuring uniform distribution of water, especially in areas where digging may be a problem. It can be usefully used in .

In other words, the impact force of water is reduced, preventing the soil from digging easily, which has a positive effect on soil conditioning and crop growth.

At this time, according to an additional aspect, the discharge pipe is characterized by including a lid 610 installed at the end of the straight section to facilitate cleaning.

Specifically, the stopper (lid) provides easy access to the interior of the discharge pipe, allowing the user to remove foreign substances, scaling, or deposits inside the pipe regularly or as needed.

In other words, opening the stopper (lid) makes it easier to clean and inspect the inside of the pipe, which plays an important role in maintaining the efficiency and lifespan of the water pipe system.

Additionally, the stopper (lid) is made of the same durable material as the pipe, so it can withstand a long period of time, and is sealed to prevent leaks or intrusion of contaminants.

Through the above configuration and operation, the present invention provides the following advantages.

First, as a precise water management, the water flow and supply amount can be precisely controlled through the water supply spout and ultrasonic flow meter of the present invention, which reduces water waste and enables efficient irrigation.

Second, by reducing digging and soil erosion, it is possible to reduce digging and soil erosion by controlling the flow rate of water, and maintain soil conditioning by allowing water to gently reach agricultural land.

Third, in terms of ease of maintenance and cleaning, the stoppers (lids) installed on the joint pipe and discharge pipe simplify cleaning and maintenance work, contributing to increasing efficiency and lifespan.

Fourth, as a quantitative data management and monitoring, ultrasonic flowmeter can accurately measure water usage and transmit data, providing essential information for managing water resources and establishing an optimized irrigation plan.

Therefore, the present invention can solve the problems of existing technologies and provide the effect of maintaining efficient management and sustainable use of water in agriculture and irrigation systems.

In the following, an example of flow rate measurement by the flow meter 400 will be described with equations.

The assumed conditions are a pipe diameter of 80 mm and a flow velocity range of 0.01 m/s to 8 m/s.

At this time, the flow rate Q can be calculated using the following formula.

Q = A * V

Here, A means the cross-sectional area of the pipe (m ² ) and V means the flow velocity (m/s).

At this time, the cross-sectional area A of the pipe can be calculated using the radius of the pipe.

A = pi * r ²

Here, r is the radius of the pipe (m), and the typical pipe radius is r = 0.04 m.

For example, when the flow velocity V is 2 m/s, the flow rate Q is calculated as follows.

First calculate the cross-sectional area of the pipe: A = pi * 0.04 ² = pi * 0.0016 = approximately 0.005 m ²

At this time, flow rate Q = 0.005 m ² * 2m/s = 0.01 m ³ /s

The flow rate calculated in this way is 0.01 cubic meters per second (m ³ /s), which represents the amount of water passing through the pipe based on data measured by an ultrasonic flow meter.

This calculation method interprets measurement data from ultrasonic flow meters and provides basic information for efficient water management in irrigation systems.

Below, we describe the code that performs the example calculation above, which calculates the flow rate based on the cross-sectional area of the pipe and the flow rate.

public class FlowRateCalculator {

public static void main(String[] args) {

double radius = 0.04; // Radius of pipe (m) - for 80

double velocity = 2.0; // Flow speed (m/s)

double area = Math.PI * Math.pow(radius, 2); // Calculate the cross-sectional area of the pipe

double flowRate = area * velocity; // flow calculation

System.out.printf("Cross-sectional area of the pipe: %.4f m²\n", area);

System.out.printf("Flow rate: %.4f m³/s\n", flowRate);

}

}

The above code does the following:

Set the radius of the pipe to 0.04 meters (equivalent to DN80), set the flow rate to 2 meters/sec, and calculate the cross-sectional area of the pipe (area = π * radius ² ).

Then, the flow rate is calculated (flowRate = area * velocity), and the calculated cross-sectional area and flow rate are output.

Therefore, the cross-sectional area and flow rate of the pipe according to given conditions are calculated and output.

Meanwhile, according to an additional aspect, the flow meter 400 of the flow check water system may further include a flow information processing unit for transmitting the currently measured flow rate information to the external terminal 2000.

Specifically, the flow information processing unit,

A digital conversion module for converting measured flow information into a digital signal;

It is configured to include a communication module for transmitting to an external terminal by supporting communication protocols such as MBus or Mdbus (RS485).

Therefore, the communication module can transmit data to a cloud server or directly to the user's mobile phone through wireless networks such as Wi-Fi, LTE, and 5G.

At this time, the collected data is stored, processed, and analyzed on the cloud server.

At this time, the user can check flow rate information in real time through an application on the smartphone, and the app displays data visually and provides warning, analysis, and reporting functions.

Meanwhile, because the security of transmitted data may be important, an encrypted communication channel is used for this purpose, and the safety of data is guaranteed through user authentication and access authority management.

With the above configuration, users can access flow meter data anytime, anywhere and obtain important information in real time for optimization of irrigation systems and efficient water management.

In addition, the user's mobile phone app is characterized by including menus such as a real-time data monitoring module, system control module, analysis and reporting module, user setting module, and warning and notification module. The menu is described in detail below. Let me explain.

The real-time data monitoring module includes a flow display layer to display the flow rate measured by the current flow meter in real time, and a statistics and history layer to record past flow rate data and display it in the form of a graph or chart.

The system control module includes a water spigot opening/closing control layer that can remotely control the opening and closing of the water spigot through an app, and a schedule setting laser for setting and managing the water supply schedule.

The analysis and reporting module includes a water usage analysis layer to evaluate irrigation efficiency by analyzing daily, weekly, and monthly water usage, and a report generation layer to generate and export reports on irrigation activities and water usage.

The user setting module includes a notification setting layer that can set a function to send notifications to the user when certain conditions are met, and a personalization setting layer that can adjust the app interface and notification settings to the user's preferences.

The specific condition is, for example, a flow rate-related condition, when the flow rate exceeds the upper limit, and a notification is sent when the set flow rate upper limit is exceeded.

For example, you can set it to send a notification when more than 100 liters of water is used per minute.

As another example, if the flow rate falls below the lower limit, a notification is sent when the flow rate falls below the set lower limit.

For example, you can set it to send a notification when water usage drops below 10 liters per minute.

As another example, in the case of a sudden change in flow rate, a notification is sent if the flow rate increases or decreases rapidly within a short period of time.

For example, you can set it to send an alert when the water volume suddenly increases from 50 liters per minute to 200 liters per minute.

Additionally, in the case of time-related conditions, when water supply starts/ends, a notification is sent when water supply starts or ends.

As another example, in the case of schedule execution, a notification is sent when the set water supply schedule is executed.

As another example, in case of long-term use, a notification will be sent if water is used for more than a certain period of time.

For example, you can set it to send you a notification if you use water continuously for more than two hours.

The warning and notification module sends an immediate warning when abnormal data is detected in the flow meter and provides notifications for regular maintenance or necessary work.

The above menus and functions allow users to effectively manage the flow check water system and perform optimized water management.

Meanwhile, the flow check flow system of the present invention may include additional components as follows.

It may be configured to further include a remote monitoring unit for controlling the opening and closing of the water supply spigot using a motor instead of the manual lever configured in the water supply spigot.

At this time, the remote monitoring unit is characterized by including the following configuration.

As a motor drive mechanism (including a motor and valve), the water spout is configured with a motor to automatically open and close by an electric motor, and the motor precisely controls the valve of the water spigot to supply water as needed.

As an electronic control module, motor operation is performed by an electronic control module, which operates the motor according to user commands or according to a set automatic operation plan.

As a remote monitoring and control module, it includes a communication interface module, which communicates with a central control server or the user's mobile via Wi-Fi, cellular network, or other wireless communication technology for remote monitoring and control.

As a mobile application/web interface module, users can monitor the status of water supply points in real time and remotely control opening and closing through a smartphone app or web interface.

With the automatic operation and scheduling module, users can program the system to open and close water spigots at specific times, optimizing water use and automating irrigation operations.

As an emergency stop module, when an emergency situation occurs, it automatically closes the water tap and maintains a safe state.

As a user interface module, the application and web interface are designed to be easy for users to understand and use.

As a real-time notification and warning module, it provides real-time notifications about system status, water usage, and other important information.

As mentioned above, by introducing a remote monitoring unit, users can manage water use more efficiently and save time and effort through automation and remote control of irrigation work, thereby improving the overall productivity of agriculture. Efficiency can be improved.

As mentioned above, the system can be programmed to open and close the water tap at specific times, and an example program for this will be described as follows.

import java.util.Timer;

import java.util.TimerTask;

public class WaterValveController {

private Timer timer;

publicWaterValveController() {

this.timer = new Timer();

}

public void scheduleValveOpen(long delay) {

timer.schedule(new TimerTask() {

@Override

public void run() {

openValve();

}

}, delay);

}

public void scheduleValveClose(long delay) {

timer.schedule(new TimerTask() {

@Override

public void run() {

closeValve();

}

}, delay);

}

private void openValve() {

System.out.println("The water supply is open.");

// Add logic to open the water supply channel here.

}

private void closeValve() {

System.out.println("The water supply is closed.");

// Add logic to close the water supply channel here.

}

public static void main(String[] args) {

WaterValveController controller = new WaterValveController();

// Water supply port scheduled to open in 5 seconds

controller.scheduleValveOpen(5000);

// The water supply port is scheduled to close in 10 seconds.

controller.scheduleValveClose(10000);

}

}

The above code is an example of using the Timer class to schedule the opening and closing of a water supply outlet after a preset delay time.

The scheduleValveOpen method and the scheduleValveClose method are examples of scheduling the tasks of opening and closing a water supply channel to be executed after a specified delay time, respectively.

The openValve method and closeValve method must include the actual logic for opening and closing the water supply channel, and in the above example, only the operation of outputting a message to the console is performed.

At this time, the code can be used to control the actual water supply stream if actual hardware and communication interfaces are implemented.

Meanwhile, according to another additional aspect, the flow rate check water stop system of the present invention,

It is characterized by further including a data management and analysis unit for utilizing data collected from the ultrasonic flow meter.

The data management and analysis department,

A data collection module for continuously collecting water flow data through a wireless network (e.g. Wi-Fi, cellular, LoRaWAN);

a database for storing and managing the collected data;

A data analysis module for analyzing water use patterns, consumption trends, abnormal situation detection, etc. based on the collected data;

A dashboard module for visualizing the analyzed data;

It is comprised of a report generation module to generate a report including the efficiency and pattern of water use based on the analyzed information.

Specifically, the data collection module performs the function of continuously collecting water flow data through a wireless network (e.g. Wi-Fi, cellular, LoRaWAN), and this data includes flow rate, flow rate, and related time information. can do.

In addition, the data analysis module performs functions to analyze water use patterns, consumption trends, and abnormal situation detection based on the collected data. For example, in the case of water use pattern analysis, daily, weekly, and monthly water By comparing usage amounts, trends in water usage changes over a specific period are analyzed to identify water usage patterns.

Additionally, by comparing water usage by day and time of day, water usage patterns are identified by analyzing differences in water usage by day of the week and time of day.

In addition, an analysis of the impact of a specific date or event can be performed, and the impact of the specific date or event (e.g., public holiday, temperature change, flood, etc.) on water usage is analyzed.

Additionally, by comparing the water usage for each user, patterns for each user can be identified.

Additionally, in the case of consumption trend analysis, long-term water usage trends can be analyzed, which analyzes long-term water usage data to determine trends in water usage increase or decrease.

In addition, the seasonal water usage trend can be analyzed, which identifies the seasonal water usage change pattern by analyzing the seasonal water usage change trend.

In addition, the water usage trend of a specific region or facility can be analyzed, which identifies differences in water usage by region or facility.

In addition, future water usage can be predicted. Based on past data, future water usage can be predicted and used to establish a water supply plan.

Additionally, in the case of abnormal situation detection, rapid changes in flow rate can be detected, and if the flow rate suddenly increases or decreases within a short period of time, water leaks or system errors are detected.

In addition, abnormal water use patterns can be detected, which can detect abnormal water use patterns that are different from usual use patterns to identify the possibility of water leaks or illegal use.

And, as shown in FIG. 6, the dashboard module performs a function to visualize the analyzed data.

In other words, the goal is to visualize data through user-friendly dashboards and make important information easily understandable.

In addition, the report generation module performs a function to generate a report including the efficiency and pattern of water use based on the analyzed information.

For example, as shown in Figure 7, the report includes report title, report creation date, reporting period, summary, flow data analysis, anomaly detection, comparison of actual use compared to irrigation plan, water use efficiency assessment, conclusion and recommendations. It is characterized by including one or more information among the details.

The above reports will help agricultural managers or irrigation system operators manage their water resources effectively and quickly make necessary adjustments, supporting data-driven decision making and ensuring sustainable and efficient operation of irrigation systems. will contribute

Meanwhile, according to additional aspects, the data management analysis unit may further include a control software module for performing irrigation schedules, sensor data processing, and automated decision-making.

The control software module may include the following configuration.

In other words, in the case of the irrigation scheduling module, automatic schedule creation takes into account weather conditions, soil moisture level, crop demand, etc., and the user can customize the irrigation schedule according to specific requirements. do.

In the case of the sensor data processing module, data collected from various sensors is integrated and analyzed in real time, which may include soil moisture status, temperature, and humidity.

And, it allows you to detect abnormalities in the data and take action.

In the case of the automated decision-making module, it provides optimization algorithms to apply algorithms to optimize water use, minimizing water waste and maximizing crop health, and automatically adjusting irrigation strategies according to environmental changes. It is to be so.

In the case of the artificial intelligence module, it learns based on collected data to improve irrigation patterns and develop prediction models, and can predict future irrigation needs by considering weather conditions, crop growth stages, etc.

Additionally, irrigation schedules can be automatically adjusted based on real-time data and prediction models.

As for the user interface module, you will have an interface that allows you to easily control and monitor your irrigation system, providing regular feedback and reports on system performance and water usage.

Meanwhile, in the following, we will explain in detail how the artificial intelligence module learns based on collected data to improve irrigation patterns and develop prediction models.

As for data collection, a variety of data will be collected from the irrigation system, which may include soil moisture, temperature, precipitation, flow rate, crop growth stage, etc.

At this time, in constructing a learning dataset, the collected data is comprised of a learning dataset. For example, data collected every day for one month may consist of 30,000 data points.

At this time, through pattern recognition and learning, the data is analyzed to learn the need for irrigation, optimal flow rate, and water use patterns by time period.

At this time, a prediction model is developed. Specifically, a prediction model optimized for irrigation is developed based on the learning data, and this model predicts future weather conditions, soil conditions, and crop requirements.

Afterwards, for testing and verification, a separate test dataset is needed to evaluate performance, and the dataset consists of actual irrigation data that was not used for learning.

Afterwards, the accuracy of the prediction is evaluated using the test dataset, which allows the actual performance and reliability of the model to be confirmed.

Afterwards, model optimization and distribution are optimized by adjusting model parameters based on test results. The optimized model is applied to an actual irrigation system, and performance is tracked through continuous monitoring.

For example, irrigation patterns will be developed by learning from six months of data (approximately 180,000 data points).

Afterwards, an additional month of collected data (approximately 30,000 data points) will be used to evaluate the model's prediction accuracy. During this evaluation, the model will predict irrigation needs for the next week based on soil moisture changes, temperature, etc. is predicted.

A model is considered successfully optimized if the predictions show high accuracy when compared to actual observed data.

In the above manner, data-based learning through AI will play an important role in increasing the efficiency of irrigation systems and optimizing resource use.

In the following, we will describe an example of automated coordination using artificial intelligence.

For example, in an irrigation system installed on a farm, the artificial intelligence module monitors soil moisture, weather conditions, and crop growth status. The artificial intelligence module analyzes these data to predict future irrigation needs, irrigation time, and amount of water. will be adjusted.

At this time, if it is a day when rainfall is expected according to the weather forecast, the artificial intelligence module adjusts the irrigation timetable based on this information to make more water available. Additionally, when the soil humidity sensor detects that enough water has been absorbed, the artificial intelligence module adjusts the irrigation schedule based on this information. The system will stop irrigation or reduce the amount of water.

Next, the artificial intelligence module predicts water demand by monitoring the growth status of the crop. While the crop is growing, the artificial intelligence module may need to provide more water and adjusts the irrigation schedule taking this into account. It will happen.

Additionally, the artificial intelligence module can learn and improve performance over time, improving the model by comparing past data with current observations and adjusting it to better adapt to the specific conditions on the farm. .

Therefore, the artificial intelligence module will intelligently control the agricultural irrigation system to enable automated adjustment and greatly contribute to improving crop productivity.

As mentioned above, when predictive analysis is performed using artificial intelligence, weather conditions, crop growth, harvest time, etc. are predicted and used to make appropriate decisions.

In particular, predictive models must be built by analyzing and learning information collected from various data sources, which may include weather data, soil conditions, crop types and growth stages, and the geographical location of the farm.

For example, artificial intelligence predictive analytics can:

In the case of weather forecasting, artificial intelligence analyzes weather data to predict weather conditions for a certain period of time in the future, which has a significant impact on crop management and irrigation decisions.

In the case of crop growth prediction, artificial intelligence predicts crop growth by considering the type and growth stage of the crop, which helps predict which stage the crop will reach at a specific time, for example, harvest time. can be used to determine .

In the case of yield prediction, artificial intelligence can predict yield based on crop growth data and weather conditions, which helps evaluate crop productivity and establish production and distribution plans in preparation for the harvest period.

In the case of crop quality prediction, artificial intelligence can analyze crop growth conditions and weather conditions to predict factors affecting crop quality, which will help improve crop quality and meet market demands.

In the following, we will explain the data and prediction results for predictive analysis.

python

Copy code

import matplotlib.pyplot as plt

# Random data: predicted crop growth status percentage

crop_growth_prediction = {

'Growing': 0.4;

'normal': 0.3;

‘Growth retardation’: 0.2;

'Anomaly found': 0.1

}

# Draw a circle graph

labels = crop_growth_prediction.keys()

sizes = crop_growth_prediction.values()

plt.figure(figsize=(8, 8))

plt.pie(sizes, labels=labels, autopct='%1.1f%%', startangle=140)

plt.title('Crop growth status prediction')

plt.axis('equal') # Keep circle graph circular

plt.show()

The above code is an example of generating a circle graph using random crop growth state prediction data, and the data can be replaced with the prediction result actually received from the model.

That is, as shown in FIG. 8, when the above code is executed, a circle graph showing the ratio of the crop growth state prediction is generated.

Meanwhile, according to another additional aspect of the present invention, the flow rate check water system 1000,

It is characterized in that it further includes a filter part between the water supply pipe 100 and the fitting pipe 200.

In other words, the water supply pipe is attached to the water channel wall and controls the opening and closing of the water, so purifying the water at this point supplies clean water to the entire system. By purifying the water before it reaches the fitting pipe, the fitting pipe and subsequent components It is possible to extend the life of devices (flanges, ultrasonic flow meters, etc.) and reduce maintenance costs.

In the case of the filter unit, a filtering module can be configured to remove large particles, suspended matter, sediment, etc. to prevent clogging of pipes or joints, and a filter that can remove chemicals, microorganisms, algae, etc. as needed. You can add

As mentioned above, the reason for installing the filter unit is to prevent contamination of rice fields existing downstream.

Specifically, if pollution from upstream rice fields, such as agricultural chemicals and fertilizers, livestock waste, domestic sewage, and factory wastewater, flows into the rice fields, it will cause crop damage, soil contamination, etc.

Accordingly, the filter unit is configured, and through this, it is possible to prevent pollution of downstream paddy fields, improve crop productivity, protect soil, preserve the ecosystem, and produce clean crops.

In order to provide the above functions, the filter unit is constructed by selecting and stacking at least one or more filter groups among screen filters, filtration filters, activated carbon filters, reverse osmosis filters, and sterilization filters.

For example, multi-stage purification can be performed by stacking various filters, and the stacking method varies depending on the desired purification level, water characteristics, purpose of use, etc.

In other words, in the case of basic filter stacking, the screen filter removes large particles such as dust, sand, and dirt, and the filtration filter reduces turbidity by removing particles with a size of 5 to 100 μm.

At this time, in the case of filter lamination for special purification, a screen filter, filtration filter, and activated carbon filter can be configured to remove odors, pigments, organic contaminants, etc.

On the other hand, screen filters, filtration filters, and reverse osmosis filters can be used to remove salts, heavy metals, viruses, etc. to supply high-purity water.

In addition, when sterilizing filters are stacked, bacteria, viruses, etc. can be removed and supplied.

Meanwhile, according to another additional aspect of the present invention, the flow rate check water system 1000,

It is characterized in that it further includes a solar panel unit.

As described above, if the solar panel unit is configured, the system can be operated stably even in irrigated areas where external power supply is unstable or absent, and the risk of system interruption due to power outage can be reduced.

In other words, it can be useful in rural areas and mountainous areas with low access to the power grid.

In this way, through the above configuration, the present invention provides sophisticated flow control and monitoring functions, thereby increasing the efficiency of water use.

In other words, it provides accurate water usage data by providing an ultrasonic flow meter and provides the effect of optimizing the flow of water through automatic or manual control.

Those skilled in the art to which the present invention pertains as described above will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not limiting.

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

100: water squirrel
200: joint pipe
300: 1st flange part
400: flow meter
500: 2nd flange part
600: discharge pipe

Claims (3)

In the flow check water system,
A water pipe 100 attached to the water channel wall 50 to control the flow and supply amount of water by controlling the opening and closing of the water through the lever 110,
A joint pipe (200) connected to the water supply pipe to control the flow rate of water,
A first flange portion 300 formed between the fitting pipe and the flow meter to firmly maintain the connection between the fitting pipe and the flow meter,
A flow meter 400 for measuring the flow rate of water supplied through the joint pipe and outputting the measured flow rate information or transmitting it to an external terminal 2000,
A second flange portion 500 formed between the flow meter and the discharge pipe to firmly maintain the connection between the flow meter and the discharge pipe,
A flow check water pipe system characterized in that it is connected to the second flange portion and includes a discharge pipe 600 for discharging water supplied through the joint pipe.
According to clause 1,
The flow meter is,
A flow rate check water stop system characterized by an ultrasonic method.
According to clause 1,
The flow meter is,
A flow check water pipe system, characterized in that it is installed in a clamping manner between the first flange portion 300 and the second flange portion 500.