KR102635596B1 - Pipe management method using ionizer and water quality sensor and system thereof - Google Patents

Abstract

According to various embodiments of the present invention, in a fluid pipe composed of an inlet and an outlet, a water quality sensor is configured inside the fluid pipe at each of the sequentially set first position, second position, and third position, In a state in which an ionization device is configured inside the fluid pipe at a fourth position set between the first position and the second position, (a) at least some of the water quality sensors configured at the first position, the second position, and the third position Receiving sensing data from and acquiring first water quality measurement information at a first time for each of the first location, the second location, and the third location based on the sensing data; (b) Future information for each of the first location, the second location, and the third location based on the sensing data, the first water quality measurement information, and the previously predicted first water quality prediction information at the first time point. determining second water quality prediction information at time 2; and (c) operating the ionization device based on the first water quality measurement information and the second water quality prediction information. Method and device for operating a management device that manages a fluid pipe using an ionization device, including can be provided.

Description

Pipe management method and system using ionizer and water quality sensor {PIPE MANAGEMENT METHOD USING IONIZER AND WATER QUALITY SENSOR AND SYSTEM THEREOF}

The present invention relates to a pipe management method and system using an ionization device and a water quality sensor, and to a method and system for checking the condition of the pipe and changes in water quality passing through the pipe and managing the pipe using an ionization device and a water quality sensor. will be.

The installation of water pipes has brought convenience to life in many homes and buildings, but as water pipes age, foreign substances are generated in the inner pipes of the water pipes, which may lead to deterioration of water quality.

For example, foreign substances that may occur in water supply pipes include nodules, rust, and organic matter growth in cuts, bends, and joints, which may cause problems not only in the pipes but also in the quality of the water passing through the pipes. In most cases, replacement of old pipes is difficult or requires a lot of cost depending on the site situation.

Approximately 25% or more of the water pipes of domestic metropolitan water supply systems are old pipes that have been used for more than 20 years, and management of these old pipes is urgently needed. Even if clean water is produced at a water purification plant, distrust in tap water may also increase as water quality deteriorates as it passes through old pipes.

In order to solve this problem, various methods for cleaning the inside of water pipes are being attempted. As an example of a water pipe cleaning method, a technology has been provided to remove contaminants within the pipe by flowing fluid within the pipe using cleaning gas. However, there is still a problem in completely removing contaminants within the pipe.

KR 10-188216

The present invention provides a method and system for managing the quality of fluid in a pipe by removing contaminants in the pipe through an ionization device and checking the quality of the fluid before and after the ionization device in the pipe.

The problems to be solved through various embodiments of the present invention are not limited to the problems mentioned, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

According to an embodiment of the present invention, in a fluid pipe including an inlet and an outlet, a water quality sensor is configured inside the fluid pipe at each of the sequentially set first position, second position, and third position, In a state in which an ionization device is configured inside the fluid pipe at a fourth position set between the first position and the second position, (a) at least some of the water quality sensors configured at the first position, the second position, and the third position Receiving sensing data from and acquiring first water quality measurement information at a first time for each of the first location, the second location, and the third location based on the sensing data; (b) Future information for each of the first location, the second location, and the third location based on the sensing data, the first water quality measurement information, and the previously predicted first water quality prediction information at the first time point. determining second water quality prediction information at time 2; and (c) operating the ionization device based on the first water quality measurement information and the second water quality prediction information. You can.

Here, the management device determines the first time point and the second time point at each of the first location, the second location, and the third location based on the first water quality measurement information and the second water quality prediction information. It is possible to determine the internal state of the fluid pipe and changes in the internal state of the fluid pipe.

Here, the management device provides first situation information including at least some of standby information, energy consumption information, and specific day information confirmed at the first time point from at least one server connected to the management device, and the second time point. Obtain second context information including at least some of predicted standby information, energy consumption information, and specific day information, and in step (b), the management device, the first context information and the second context information. The second water quality prediction information can be determined by further considering.

Here, when operating the ionization device in step (c), the management device is based on the first water quality measurement information, the second water quality prediction information, and the flow rate measured for the fluid inside the fluid pipe. The ionization degree of the fluid can be adjusted through an ionization device.

Here, the management device may control the flow rate of the fluid based on the water quality of the fluid pipe, the temperature of the fluid, and the flow rate of the fluid.

Here, the second water quality prediction information is situation information about a plurality of specific times in the past. It may be determined based on an algorithm set to calculate water quality prediction information for situational information at a specific point in the future based on water quality measurement information and water quality prediction information.

Here, the management device may reset the algorithm after the second time point based on the second water quality prediction information predicted at the second time point and the second water quality measurement information measured at the second time point.

Here, the management device determines the location and amount of water leakage based on the sensing data and the flow rate measured for the fluid inside the fluid pipe at each of the first location, the second location, and the third location. and obtains vibration information measured through a vibration sensor configured at at least a portion of the pipe. In step (b), the management device further considers the location and amount of water leakage and the vibration information. The second water quality prediction information may be determined.

According to another embodiment of the present invention, in a fluid pipe including an inlet and an outlet, a water quality sensor is configured inside the fluid pipe at each of the sequentially set first position, second position, and third position, With an ionization device configured inside the fluid pipe at a fourth position set between the first position and the second position, at least one water quality sensor included in the first position, the second position, and the third position A communication unit connected to the sensor and the ionization device; And receiving sensing data from at least some of the water quality sensors configured at the first location, the second location, and the third location, and detecting the first location, the second location, and the third location based on the sensing data. Obtain first water quality measurement information at a first time point for each, and based on the sensing data, the first water quality measurement information, and the predicted first water quality prediction information at the first time point, the first location, the first Determining second water quality prediction information at a second time in the future for each of the two locations and the third location, and processing to operate the ionization device based on the first water quality measurement information and the second water quality prediction information A management device that manages fluid pipes using an ionization device, including a processing unit, can be provided.

According to various embodiments of the present invention, the durability of water pipes can be improved by removing contaminants in the pipes through an ionization device and preventing damage to the pipes due to accumulation of contaminants in the pipes.

According to various embodiments of the present invention, the manpower required for pipe maintenance can be reduced by managing the condition and water quality of buried pipes through an ionization device, and thus maintenance costs can be effectively reduced.

According to various embodiments of the present invention, damage to pipes or contamination within pipes can be easily confirmed and responded to, thereby greatly improving the health and hygiene level of buildings.

1 is a diagram showing the configuration of a management device according to an embodiment of the present invention.
Figure 2 is a diagram showing the approximate configuration of a management device according to an embodiment of the present invention, an ionization device and sensor connected to the management device, and piping in which the ionization device and sensor are installed.
Figure 3 is a diagram showing the flow of operations for managing pipes in a management device according to an embodiment of the present invention.
Figure 4 is a diagram showing the approximate configuration of a management device according to another embodiment of the present invention, an ionization device and sensor connected to the management device, and piping in which the ionization device and sensor are installed.

Hereinafter, embodiments will be described in detail with reference to the attached drawings. However, since various changes can be made to the embodiments, the scope of rights of the patent application is not limited or limited by these embodiments. It should be understood that all changes, equivalents, or substitutes for the embodiments are included in the scope of rights.

The terms used in the examples are for descriptive purposes only and should not be construed as limiting. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the embodiments belong. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and unless explicitly defined in the present application, should not be interpreted in an ideal or excessively formal sense. No.

In addition, when describing with reference to the accompanying drawings, identical components will be assigned the same reference numerals regardless of the reference numerals, and overlapping descriptions thereof will be omitted. When describing an embodiment, if it is determined that a detailed description of related known technology may unnecessarily obscure the gist of the embodiment, the detailed description will be omitted.

Additionally, when describing components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being “connected,” “coupled,” or “connected” to another component, that component may be directly connected or connected to that other component, but there is no additional component between each component. It should be understood that may be “connected,” “combined,” or “connected.”

Components included in one embodiment and components including common functions will be described using the same names in other embodiments. Unless stated to the contrary, the description given in one embodiment may be applied to other embodiments, and detailed description will be omitted to the extent of overlap.

‘Data’ processed in the management device can be expressed in terms of ‘information’. Here, information may be used as a concept including data.

The present invention relates to a pipe management method and system using an ionization device and a water quality sensor. More specifically, the present invention relates to a pipe management method and system that uses an ionization device installed inside the pipe to clean foreign substances inside the pipe, and to clean the pipe and water quality through a water quality sensor. Explains the piping management method and system for checking and predicting.

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. The drawings attached to this specification serve to further understand the technical idea of the present invention along with the detailed description of the invention, so the present invention is described in the drawings. It should not be interpreted as limited to the specific details.

1 is a diagram showing the configuration of a management device according to an embodiment of the present invention.

Referring to FIG. 1, the management device 100 for managing pipes may include a processing unit 110, a storage unit 120, a communication unit 130, and an input/output unit 140. Here, the management device 100 is shown as including the communication unit 130, but it is not limited to this, and the communication unit 130 may be selectively determined to be included/not included at the design and/or manufacturing stage.

The processing unit 110 of the management device 100 may process the operation of the ionizer and/or water quality sensor through artificial intelligence (AI). In addition, the processing unit 110 of the management device 100 analyzes the sensing data obtained from the water quality sensor through artificial intelligence, and controls the functions of the management device 100 and/or peripheral devices (e.g., ionizer, and/or other devices). Internet of Things (IoT) technology that controls electronic devices may be applied.

The processing unit 110 analyzes the sensing data received from the water quality sensor through at least one program (app, application, tool, plug-in, etc., hereinafter referred to as a pipe management program), and processes control commands to control the ionization device based on this. can do. At this time, the pipe management program may be stored in the storage unit 120 of the management device 100 and/or the storage unit of an external device connected to the management device 100.

The processing unit 110 may share data processing with at least one device (eg, a manager device) connected to the management device 100 through a pipe management program.

For example, the processing unit 110 may store sensing data received from the ionization device and/or sensors connected to the management device 100 in the storage unit 120 and/or at least one server.

The processing unit 110 can output the determined and predicted states related to piping and/or water quality through the display unit of the management device 100, and/or transmit them to a manager device connected to the management device 100. there is.

Hereinafter, in various embodiments, the management device 100 processes a control command (hereinafter referred to as a control command) for pipe management by performing events specified through at least one pipe management-related program of the management device 100. It can be understood that

Here, the control command processing is described as being performed through a pipe management program installed in the management device 100, but the process is not limited to this and may be performed through another pre-installed program or a temporary installation program.

According to one embodiment, processing of control commands may be performed through at least part of a database provided free of charge or for a fee from a device external to the management device 100.

The operation of the management device 100 is performed based on the data processing and device control of the processing unit 110, and the processing unit 110 can perform designated functions based on control commands confirmed from touch input on the touch screen. .

The storage unit 120 may store various data processed by at least one component of the management device 100 (e.g., the processing unit 110 or the communication unit 130). The data may be used for, for example, pipe management. It may include a program (or software) for, and input data or output data related thereto.

The storage unit 120 is an artificial intelligence system that includes at least some of an artificial neural network algorithm, a blockchain algorithm, a deep learning algorithm, a regression analysis algorithm, and mechanisms, operators, language models, and big data related thereto for analyzing and processing sensing data. May include algorithms.

For example, the storage unit 120 performs an algorithm for determining water quality and changes in water quality based on sensing data obtained through a water quality sensor, and/or performs a specified operation (e.g., control of an ionization device) in relation to this. It may include an algorithm for

Additionally, the storage unit 120 may include at least one algorithm for managing pipe status and water quality, such as a sensing data analysis algorithm and an ionization device control algorithm.

The storage unit 120 may include data for determining and processing control and operation of devices through data received through the communication unit 130 and/or the input/output unit 140.

The operations described through the storage unit 120 are processed by the processing unit 110, and data for processing related operations, data in process, processed data, preset data, etc. are stored in the storage unit 120 as a database. You can.

The data stored in the storage unit 120 is changed, modified, deleted, and processed by the processing unit 110 based on the administrator input of the management device 100 or the administrator input of the manager device (or user device) connected to the management device 100. /Or new data can be created.

The storage unit 120 may store device setting information of the management device 100. The device setting information may be setting information for at least some of the functions of the management device 100.

The storage unit 120 may store user information for at least one user. For each user information, at least some of user identification information (eg, identification, ID), password, and user customized setting information may be stored. User-customized setting information is setting information for control authority and/or at least some of the functions of the management device 100, and can be set and stored according to administrator input.

The storage unit 120 may be configured to include volatile memory or non-volatile memory.

The communication unit 130 supports establishment of a wired communication channel between the management device 100 and at least one other electronic device (e.g., a manager device or server), establishment of a wireless communication channel, and performance of communication through the established communication channel. You can.

The communication unit 130 operates dependently or independently of the processing unit 110 and may include one or more communication processors that support wireless communication. According to one embodiment, the communication unit 130 is a wireless communication module (e.g., a cellular communication module, a short-range wireless communication module, or a global navigation satellite system (GNSS) communication module) or a wired communication module (e.g., a local area network (LAN)) may include a communication module, or a power line communication module).

The communication unit 130 is a short-range communication network such as Bluetooth, BLE (Bluetooth Low Energy), WiFi, WiFi direct, IrDA (infrared data association), ZigBee, UWB, and RF (Radio Frequency) and/or a cellular network, the Internet, or a computer network. It is possible to communicate with an external electronic device (or external device) through a long-distance communication network (e.g., LAN or WAN).

Various types of communication modules constituting the communication unit 130 may be integrated into one component (e.g., a single chip) or may be implemented as a plurality of separate components (e.g., multiple chips).

The input/output unit 140 may include at least one display unit (eg, display) for outputting information related to piping management. In addition, the input/output unit 140 may further include at least some of an input unit (not shown) that inputs data, such as a microphone, keyboard, or mouse, and an output unit (not shown) that outputs data, such as a speaker or a driver.

According to various embodiments of the present invention, the management device 100 or manager device performs at least some of the functions of all information and communication devices, including mobile communication terminals, multimedia terminals, wired terminals, fixed terminals, and internet protocol (IP) terminals. may include.

The management device 100 is a device for piping management and may be configured to include at least some functions of a workstation or a large-capacity database or to be connected through communication.

Manager devices connected to the management device 100 include mobile phones, personal computers (PCs), portable multimedia players (PMPs), mobile internet devices (MIDs), smartphones, tablet PCs, and tablets. Examples include bullet PCs and laptops.

According to various embodiments of the present invention, the manager device can be described as a device that manages pipe management of the management device 100.

Here, a server is an entity that exists on a network and performs the roles of a web server, database server, and application server. According to a preferred embodiment, the server may provide various contents to the management device 100 and/or the manager device based on processing of the management device 100.

As shown in FIG. 2, the management device 100 may be connected to at least one ionization device and/or water quality sensor installed in the pipe through the communication unit 130. According to various embodiments of the present invention, a piping management system can be configured including a management device 100, an ionization device, and a water quality sensor.

Figure 2 is a diagram showing the approximate configuration of a management device according to an embodiment of the present invention, an ionization device and sensor connected to the management device, and piping in which the ionization device and sensor are installed.

The piping management system 200 may include a fluid piping 21 through which fluid (eg, water, gas) flows in and out. In various embodiments of the present invention, the fluid pipe 21 is described as a water pipe 21 for water or sewage, and the fluid flowing through the fluid pipe 21 is described as a water resource (water), but it is not limited to this and various Fluid piping and/or fluid may be applied.

Likewise, according to various embodiments of the present invention, water quality sensors are expressed as sensors installed in water pipes to measure water quality, but the water quality sensor is not limited to this, and also various types of water quality sensors measure fluid quality depending on the type of fluid. Sensors may be applied.

The pipe management system 200 includes a water pipe 21, water quality sensors 201, 203, 205, an ionizer 211, and water quality sensors 201, 203, 205 installed inside a specific location of the water pipe 21. It may be configured to include a management device 100 that receives sensing data from and controls the ionization device 211.

The water pipe 21 configured in the pipe management system 200 of FIG. 2 represents a fluid pipe configured to allow fluid (hereinafter referred to as water) flowing in 221 to flow out into the house 23. However, the water pipe 21 may be configured to discharge to various places, such as buildings and other water pipes, as well as the house 23.

Referring to FIG. 2, the water pipe 21 of the pipe management system 200 may be configured to have three water quality sensors 201, 203, and 205 and one ionization device.

For example, the water quality sensors (201, 203, 205) and the ionizer 211 are configured inside the water pipe 21, and a first water quality sensor ( 201), the ionization device 211, and the second water quality sensor 203 may be sequentially configured in the direction of the outlet (or end point). In addition, the third water quality sensor 207 may be configured at a designated location from the outlet of the water pipe.

Here, the inlet may refer to a location where water flows in from a designated water pipe configuration, and the outlet may refer to a location where water flows out from the designated water pipe configuration to another water pipe. According to this, the outlet of the water pipe 21 in FIG. 2 may be the inlet of the water pipe (not shown) of the house 23.

In the water pipe 21 of the pipe management system of FIG. 2, each of the water quality sensors 201, 203, and 205 may be configured as a water quality sensor group including two or more sensors. At this time, each of the water quality sensors 201, 203, and 205 may be configured to include at least one sensor with another function.

For example, the water quality sensor may be configured to include at least one sensor among sensors capable of measuring turbidity, salinity, heavy metals, water temperature, ions, and organic matter information.

In addition, at least one sensor among a vibration sensor, a water pressure sensor, and a flow rate sensor may be configured at the location of at least one water quality sensor or a specific location in the pipe. According to various embodiments of the present invention, when a water quality sensor is configured to include a plurality of sensors (consisting of a water quality sensor group), the term water quality sensor includes at least one sensor among a vibration sensor, a water pressure sensor, and a flow rate sensor. It can also be explained as: That is, the water quality sensor may be configured to include at least one sensor among a vibration sensor, a water pressure sensor, and a flow rate sensor.

The water pipe 21 constituting the pipe management system 200 of FIG. 2 includes a first water quality sensor 201, a second water quality sensor 203, a third water quality sensor 205, and one ionization device 211. ) has been described as being disposed, but it may also be configured to further include at least one water quality sensor and/or at least one ionization device.

Figure 3 is a diagram showing the flow of operations for managing pipes in a management device according to an embodiment of the present invention.

In the water pipe management method using the ionization device and water quality sensor of the management device 100, the water quality sensor may be installed at a plurality of locations in the water pipe for the purpose of water quality management.

According to one embodiment, as explained through FIG. 2, the water pipe 21 has a first water quality sensor 201 installed at the first position of the inlet through which water flows 221, and after the first water quality sensor The second water quality sensor 203 is installed at the second position, the third water quality sensor 9205 is installed at the third position of the outlet through which water flows out of the water pipe 21, and the ionization device 211 is, It may be installed in a fourth position between the first position and the second position.

Sensors included in the water quality sensor may be supplied with power from an independent power supply or from the management device 100, and in step 301(a), the management device 100 operates at the first location, the second location, And receiving sensing data from at least some of the water quality sensors configured at the third location, and determining the first water quality at the first point in time for each of the first location, the second location, and the third location based on the sensing data. Measurement information can be obtained.

According to one embodiment, the management device 100 receives sensing data measured in real time or in designated time units from the first water quality sensor 201, the second water quality sensor 203, and the third water quality sensor 205. You can receive it.

The management device 100 determines the first position based on the sensing data measured at the first time among the sensing data received from the first water quality sensor 201, the second water quality sensor 203, and the third water quality sensor 205. , the first water quality measurement information at the first point in time for each of the second location and the third location can be obtained.

That is, the management device 100 can obtain water quality measurement information for each sensor location from the acquired sensing data at each time the sensing data is measured.

In step 303(b), the management device 100 determines the first location and the second location based on the sensing data, the first water quality measurement information, and the predicted first water quality prediction information at the first time point. , and second water quality prediction information at a second time in the future for each of the third locations may be determined.

The management device 100 may determine water quality prediction information for a specific point in time based on at least one algorithm for predicting water quality (hereinafter, water quality prediction algorithm). Here, the water quality prediction information for a specific point in time may be water quality prediction information for a specific water quality sensor location, or may be water quality prediction information determined as an average value for two or more water quality sensor locations.

In addition, the management device 100 is not limited to determining water quality prediction information for the water quality sensor location, but may also determine water quality prediction information for a specific location in the water pipe 21 where the water quality sensor is not located.

The water quality prediction algorithm may be based on at least one artificial intelligence algorithm and may include at least one mathematical equation. According to one embodiment, the water quality prediction algorithm may be configured based on at least some of various artificial intelligence algorithms such as machine learning, deep learning, regression analysis, and big data analysis.

The water quality prediction algorithm includes water quality prediction information predicted for a plurality of times in the past, measured water quality measurement information, and at least some of these (e.g., water quality prediction information predicted for a plurality of times in the past, measured water quality measurement information). It may be an algorithm configured to calculate water quality prediction information for a specific point in the future based on changes.

For this purpose, the storage unit 120 includes a piping diagram for the water pipe 21, the location where the water quality sensor of the water pipe 21 is configured, water quality measurement information measured at each water quality sensor at a specific time in the past, and a specific time in the future. Water quality prediction information predicted for and a matching table in which this information is matched may be stored.

When the management device 100 reaches the time point of the predicted water quality prediction information and receives the water quality measurement information measured at that time point, the management device 100 matches the obtained water quality measurement information with the corresponding water quality prediction information in the matching table to store the storage unit 120. ) can be saved in .

Here, the water quality measurement information measured at a specific time in the past may be water quality measurement information measured at a specific time in the past at two or more locations in the water pipe. In addition, water quality prediction information predicted for a specific point in the future may be water quality prediction information predicted at a specific point in the future at a specific location in the water pipe.

In addition, the water quality prediction algorithm may be an algorithm configured or reconfigured to match water quality prediction information predicted by a water quality sensor at a specific point in time with water quality measurement information measured at a specific point in time.

In more detail, the management device 100 determines the first location at the first time point, the second location at the first time point based on the water quality prediction algorithm before receiving the sensing data at the first time point, that is, before step 301(a). The first water quality prediction information for at least some of the location and the third location may be determined.

When the water quality prediction algorithm at this time is referred to as the first water quality prediction algorithm, the management device 100 can determine the second water quality prediction information at a second time in the future using the first water quality prediction algorithm.

However, the management device 100 reconfigures the water quality prediction algorithm based on the first water quality prediction information at the first time, the first water quality measurement information, and the first water quality prediction algorithm, and uses the reconstructed second water quality prediction algorithm. Based on this, second water quality prediction information at a second time point can be determined.

According to one embodiment, the second water quality prediction algorithm is such that the management device 100 uses the first water quality prediction algorithm to match the first water quality prediction information for at least one location with the first water quality measurement information for the location. By modifying, a second water quality prediction algorithm may be created (or regenerated, reset).

In addition, when determining water quality prediction information, the management device 100 may further consider situational information including at least some of atmospheric information, energy consumption information, and specific day information.

When considering further situational information, the water quality prediction algorithm calculates water quality prediction information for specific situational information at a specific point in the future based on water quality prediction information predicted for situational information at past points in time and measured water quality measurement information. It may be a configured algorithm.

Here, the situation information may be information received from the server after being predicted, measured, collected, acquired, and/or processed from an external device (eg, server) connected to the management device 100.

For example, situation information can be received from at least one server among public institutions such as the Korea Meteorological Administration, Ministry of Land, Infrastructure and Transport, and Statistics Korea, but is not limited to this and can be received from various servers (e.g., servers of companies, individuals, etc.). there is.

Various servers connected to the management device 100 may operate based on at least one application programming interface (API).

Here, the atmospheric information may include information on at least some of weather, temperature, fog, precipitation, rainfall, season, solar environment, ozone, ultraviolet rays, magnetic field, fine dust, carbon dioxide, and carbon monoxide.

Energy consumption information may include information on at least some of power usage, gas usage, and water usage. Furthermore, the energy consumption information may further include information on at least some of the power plant's coal usage, oil usage, water usage, and nuclear energy usage.

Specific day information may include information about at least some of year, month, day, day of the week, anniversary, holiday, and public holiday.

However, the management device 100 is not limited to the above-described standby information, energy consumption information, and specific date information, and can receive information such as noise, earthquake, construction, accidents, and water leaks from a server connected to the management device 100. Context information can be configured by including at least some of various information.

The management device 100 can fuse the received situation information with water quality information that matches it (e.g., water quality prediction information or water quality measurement information) and extract various information related to pipes and water quality.

For example, the management device 100 receives first situation information and second information including at least some of standby information, energy consumption information, and specific day information at a first time from at least one server connected to the management device 100. Second situation information including at least some of the point-in-time standby information, energy consumption information, and specific day information may be obtained.

The management device 100 matches the acquired first context information with the first water quality prediction data and/or first water quality measurement data of the matching data, and matches the second context information with the second water quality prediction data of the matching data. You can.

That is, the storage unit 120 includes the piping diagram for the water pipe 21, the location where the water quality sensor of the water pipe 21 is configured, the water quality measurement information measured at each water quality sensor at a specific time in the past, and the water quality measurement information at a specific time in the future. Water quality prediction information and a matching table in which this information is matched are stored, and situational information for each time point can be stored together in a matched state.

Here, when the situation information is divided based on two or more conditions, such as prediction information and measurement information, the divided situation information may be matched with the water quality prediction information and/or the water quality measurement information as separate information.

According to the above, when situational information is further considered, water quality prediction information predicted for the situation at past points in time, measured water quality measurement information, and these (e.g. water quality prediction information predicted for the situation at past points in time, measured water quality information predicted for the situation at past points in time) It may be an algorithm configured to calculate water quality prediction information for a specific point in the future based on changes in at least some of the water quality measurement information.

According to one embodiment, the management device 100, at a time before receiving the sensing data at the first time point, that is, before step 301(a), based on a water quality prediction algorithm, the first time point and the first time point at the first time point. In the first situation according to the situation information, the first water quality prediction information for at least some of the first location, the second location, and the third location may be determined.

When the water quality prediction algorithm at this time is referred to as the first water quality prediction algorithm, the management device 100 can determine the second water quality prediction information at a second time in the future using the first water quality prediction algorithm, as described above. .

However, the management device 100 reconfigures the water quality prediction algorithm based on the first water quality prediction information, first water quality measurement information, and the first water quality prediction algorithm for the first time point and the first situation at the first time point, and , Based on the reconstructed second water quality prediction algorithm, second water quality prediction information for the second situation according to the second situation information at the second point in time may be determined.

According to one embodiment, the second water quality prediction algorithm is such that the management device 100 uses the first water quality prediction algorithm to match the first water quality prediction information for at least one location with the first water quality measurement information for the location. By modifying, a second water quality prediction algorithm may be created (or regenerated).

According to the above, the management device 100 is described as calculating water quality prediction information based on a water quality prediction algorithm, but this is not limited to calculation (or operation) processing according to a mathematical equation, and the same is used through a mapping table. Alternatively, the value of the most similar state may be determined, and these methods may be combined to determine water quality prediction information.

When reconstructing the water quality prediction algorithm, the management device 100 may reconstruct the water quality prediction algorithm when the difference between the water quality prediction information and the water quality measurement information value exceeds a preset difference value.

According to one embodiment, the management device 100 determines the difference between the water quality prediction information and the water quality measurement information value based on the average value of the water quality measurement information measured by each of the water quality sensors and the average value of the predicted water quality prediction information. You can.

In step 305(c), the management device 100 may operate the ionization device based on the first water quality measurement information and the second water quality prediction information.

According to one embodiment, the management device 100 operates the ionization device 211 when the water quality inside the water pipe 21 at a specific point in the future, that is, the value of the second water quality prediction information, exceeds a preset limit value. can do.

In the present invention, the value of water quality measurement information and/or the value of water quality prediction information may indicate water quality. For example, while the inside of the water pipe 21 is always filled with water, the inside of the water pipe 21 becomes contaminated over time, and this state of the water pipe 21 is caused by the water flowing through the water pipe 21. It may affect water quality.

The management device 100 monitors the state (e.g., pollution level) inside the water pipe 21 based on the water quality measured and/or predicted at a location inside the water pipe 21, that is, based on the water quality inside the water pipe 21. ) can be determined.

In other words, the management device 100 may determine that the contamination inside the water pipe 21 progresses as the average water quality decreases and/or as the water quality at a specific location becomes relatively low.

Accordingly, the management device 100 is configured to control the The ionization device 211 can be operated to clean the interior. At this time, the operating level of the ionization device 211 can be differentially controlled according to the degree to which the value of the second water quality prediction information exceeds a preset limit value.

For example, in the setting information of the management device 100, if the water quality information (water quality prediction information or water quality measurement information) value exceeds a preset limit value, the water quality information values are divided into a plurality of levels according to the water quality. As the water quality decreases (or the value of the second water quality prediction information increases), the number of levels according to water quality increases (e.g., first level, second level, etc., the higher the number, the lower the water quality). It may be a state.

Additionally, in the setting information of the management device 100, the operation of the ionization device 211 is divided into a plurality of levels, and each level can be divided according to the degree of ionization of water. At this time, the number of operation levels of the ionization device 211 may be set to increase as the ionization device operates more strongly.

In addition, in the setting information of the management device 100, each of a plurality of levels according to the degree of water quality may be matched to each operation level of the ionization device, and the management device 100 may have a state corresponding to the level of water quality. The ionization device 211 can be operated according to the operation level of the ionization device.

In addition, the management device 100, in a state where the water quality exceeding the limit value is divided into a plurality of levels (first level, second level, third level, and fourth level, etc.), the water quality exceeding the limit value is set to a specific level. If it exceeds this, at least one pipe cleaning device may be operated in addition to the ionization device.

For example, the water pipe 21 may be further configured with at least one pipe cleaning device selected from the group consisting of a bubble generator and/or a vortex generator toward the outlet of the ionization device 211. To explain in more detail, in addition to the ionization device 211, a first cleaning device and a second cleaning device may be further configured in the direction of the outlet of the water pipe 21.

At this time, the management device 100 operates the ionization device 211 and the first cleaning device together when the water quality exceeding the limit value is at the third level, and when the water quality exceeding the limit value is at the fourth level, the ionization device 211 , the first cleaning device, and the second cleaning device can be operated together.

According to various embodiments, the management device 100, in a state where the water quality according to the first water quality measurement information is lower than the water quality according to the second water quality prediction information, the difference between the first water quality measurement information and the second water quality prediction information value If it exceeds the preset limit difference value, the ionization device 211 can be operated. At this time, the level at which the ionization device 211 is operated can be differentially controlled according to the degree to which the difference between the first water quality measurement information and the second water quality prediction information value exceeds a preset limit difference value.

In the present invention, the difference between the first water quality information (the water quality information may be water quality prediction information or water quality measurement information) and the second water quality information value is a change in water quality, and the internal state of the water pipe 21 (e.g. : It may indicate a change in pollution level.

According to one embodiment, the management device 100, based on the average value of the first water quality measurement information measured by each of the water quality sensors and the average value of the second water quality prediction information predicted for each of the water quality sensors, The difference between the water quality measurement information and the second water quality prediction information value can be determined.

However, without being limited thereto, the management device 100 determines the difference between the first water quality measurement information and the second water quality prediction information value for at least a portion of the water pipe 21, that is, a water quality sensor at a specific location. It can be determined by the difference between the water quality measurement information and the second water quality prediction information value.

The management device 100 operates according to the water quality measured and/or predicted at a location inside the water pipe 21 and the water quality predicted at a subsequent measurement time based on this, that is, the state inside the water pipe 21 (e.g. : Pollution level) changes can be determined.

For example, the management device 100, based on the first water quality measurement information and the second water quality prediction information, controls the water pipes at the first time point and the second time point in at least part of the first location, the second location, and the third location. It is possible to determine the internal condition and changes in the internal condition of the water pipe.

In other words, a state in which contamination of the water pipe 21 progresses over time, that is, water quality in which water quality prediction information after a certain point is lower than the value of water quality measurement information at a certain point in time (higher degree of contamination). In a state having a value of there is.

Accordingly, the management device 100 provides water quality information (e.g., first water quality measurement information) at a specific point in time (e.g., first point in time) and some point in time (e.g., second point in time) after a specific point in at least some of the sensors. If the difference between the values of water quality information (e.g., second water quality prediction information) exceeds the limit difference value, the ionization device 211 may be operated to clean the inside of the water pipe 21.

At this time, the management device 100 may differentially control the level at which the ionization device 211 is operated according to the degree to which the difference between the first water quality measurement information and the second water quality prediction information value exceeds a preset limit difference value. there is.

For example, in the setting information of the management device 100, when the difference between the first water quality measurement information and the second water quality prediction information value exceeds a preset limit difference value, the internal state of the water pipe 21 (e.g. Pollution degree) and/or the difference between the first water quality measurement information and the second water quality prediction information corresponding to the change is divided into a plurality of levels, and as the change in water quality increases (or the first water quality measurement information and the second water quality prediction information As the difference in information value increases, the number of levels according to the change in water quality may be set to increase (e.g., first level, second level, etc., the higher the number, the greater the change).

Additionally, in the setting information of the management device 100, the operation of the ionization device 211 is divided into a plurality of levels, and each level can be divided according to the degree of ionization of water. At this time, the number of operation levels of the ionization device 211 may be set to increase as the ionization device operates more strongly.

In addition, in the setting information of the management device 100, each of a plurality of levels according to the degree of change in water quality may be matched to each operation level of the ionization device, and the management device 100 may match the level of change in water quality. The ionization device 211 can be operated according to the operation level of the corresponding ionization device.

In addition, the management device 100, in a state where the water quality change exceeding the limit difference value is divided into a plurality of levels (first level, second level, third level, and fourth level, etc.), the water quality change exceeding the limit difference value If exceeds a certain level (ex level 3), at least one pipe cleaning device can be operated in addition to the ionization device.

For example, the water pipe 21 may be further configured with at least one pipe cleaning device selected from the group consisting of a bubble generator and/or a vortex generator toward the outlet of the ionization device 211. To explain in more detail, in addition to the ionization device 211, a first cleaning device and a second cleaning device may be further configured in the direction of the outlet of the water pipe 21.

At this time, the management device 100 operates the ionization device 211 and the first cleaning device together when the water quality change exceeding the limit difference value is at the third level, and when the water quality change exceeding the limit difference value is at the fourth level, the management device 100 operates the ionization device 211 and the first cleaning device together. The device 211, the first cleaning device, and the second cleaning device can be operated together.

According to various embodiments, when operating the ionization device, the management device 100 controls the flow of fluid through the ionization device based on the first water quality measurement information, the second water quality prediction information, and the flow rate measured inside the water pipe. Ionization degree can be adjusted.

For example, the management device 100 may be connected to at least one flow rate sensor configured inside the water pipe 21. For example, at least some of the sensors configured in the water pipe 21 may include a flow rate sensor.

When operating the ionization device 211, the management device 100 may control the operation level of the ionization device 211 according to the measured flow rate. For example, when the flow rate of fluid is low, the management device 100 can control the ionization degree of the ionization device 211 to be high (control the operation level to be high).

To this end, the setting information of the management device 100 may be matched so that the ionization degree (operation level) of the ionization device 211 increases as the fluid flow rate slows.

According to various embodiments, the management device 100 determines whether a water leak occurs based on the sensing data received from the water pipe 21 and the flow rate measured in at least some of the first location, second location, and third location. The location and amount of leakage can be determined.

When performing step 303(b), the management device 100 predicts the second water quality by further considering at least some of the vibration information, flow rate, water leak location, and water leak amount measured through a vibration sensor configured in at least a portion of the pipe. information can be determined.

As described above, the management device 100 determines whether the water quality predicted for a specific future point in time (e.g., a second point in time) is lower than the preset water quality, or if the water quality predicted for a specific point in the future (e.g., a second point in time) is lower than the preset water quality. If the water quality change becomes greater than the preset water quality change, it is determined that the contamination of the water pipe 21 is outside the limit, and the ionizer 211 and/or various pipe cleaning devices are operated to clean the inside of the pipe depending on the degree of contamination. You can.

Although not shown in Figure 3, according to various embodiments of the present invention, the management device 100 may be configured to further include at least one vibration sensor.

For example, the vibration sensor may be configured outside the pipe at at least one of the water quality sensor locations (e.g., first position, second position, third position, etc.) of the water pipe 21.

The management device 100 receives vibration applied to the water pipe 21, which is measured through a vibration sensor, and controls the water pipe 21 based on the vibration (and/or shock) accumulated in the water pipe 21. It is possible to determine whether there is damage (e.g. cracks).

In addition, the management device 100 compares the magnitude of the impact applied to the water pipe 21, measured through a vibration sensor, with the limit impact of the water pipe 21 to determine whether the water pipe 21 is damaged. You can.

Here, when a crack occurs in the water pipe 21, external contaminants, etc. may flow into the water pipe 21 through the crack, thereby accelerating contamination of the water pipe 21.

As described above, the contamination of the internal state of the water pipe can be determined based on the water quality and/or water quality change information that the management device 100 receives from the water quality sensor. The management device 100 may determine pipe damage occurring at a specific location of the water pipe 21 based on sensing data received through the vibration sensor.

The management device 100 measures water quality and changes in water quality and obtains water quality prediction information through a water quality sensor at the location where damage to the water pipe 21 occurs, and based on this, uses an ionization device 211 and/or a pipe cleaning device. can be operated.

Measure and/or predict water quality information about water quality and/or water quality change at a specific location where damage to the water pipe 21 occurred, determine the state and/or change in state of the pipe based on this, and ionization device ( 211) and/or the method of operating the pipe cleaning device and the device may be configured the same or similar to the steps of FIG. 3, and if the content is redundant, the description may be omitted.

According to the above, when the management device 110 confirms pipe damage at a specific location of the water pipe 21, the ionization device 211 and/or the pipe cleaning device can be modified to operate the specified location at the specific location. .

For example, in the setting information of the management device 100, the level (level for water quality) corresponding to the second water quality prediction information value and/or the difference between the first water quality measurement information and the second water quality prediction information value is set to the third water quality prediction information value. If it is above the level, the ionization device 211 may be set to operate. In this state, the management device 100 may determine that the water pipe at a specific location of the water pipe 21 is damaged.

When damage occurs on the water pipe 21, the management device 100 can modify the setting information so that the ionization device 211 is operated even when the water quality level is not the third level or higher but the second level or higher. there is.

In more detail, when the management device 100 confirms that the pipe is damaged at a specific location, for example, the fifth position between the fourth position and the third position of the water pipe 21, the management device 100 ) is the level (level for water quality) that serves as the operation standard of the ionizer 211 for the ionizer 211 designated to manage the water quality and/or piping condition at the fifth location where damage to the water pipe 21 was confirmed ) can be modified (e.g., modified from the third level to the second level as described above).

The management device 100 may control the operation level of the ionization device 211 according to the degree of pipe damage determined according to water quality and/or changes in water quality.

For example, in the setting information of the management device 100, the degree of pipe damage may be divided into a plurality of levels, and each level may be matched to the operation level of the ionization device 211.

In addition, the management device 100 determines the operation of the ionization device 211 and/or the pipe cleaning device by comprehensively considering the degree of pipe damage, pipe damage location, water quality, and/or water quality change of the water pipe 21. You can.

The management device 100 is based on the degree of damage to the water pipe 21, and even if the inside of the pipe is cleaned through the ionization device 211 and/or the pipe cleaning device, the water quality (and/or the internal condition of the pipe) cannot be improved. The condition can be judged and determined to be a damaged pipe. When determining the state of pipe damage, the management device 100 outputs a notification about the location and pipe damage through the display unit of the management device 100, and/or transmits it to a manager device connected to the management device 100. can do.

When the second time point is reached, the management device 100 may receive sensing data on second water quality specific information at the second time point from sensors inside the pipe. The management device 100 may modify the water quality prediction algorithm based on the measured second water quality measurement information and the second water quality prediction information.

Here, the management device 100 may modify the water quality prediction algorithm using the same or similar method as described in step 303(b).

According to the above description, the management device 100 is a pipe management device consisting of a water quality sensor and an ionization device installed at the outlet and inlet of the water pipe 21 as a set. However, the piping management system is not limited to this and may be configured to include a water piping having two or more outlets.

Figure 4 is a diagram showing the approximate configuration of a management device according to another embodiment of the present invention, an ionization device and sensor connected to the management device, and piping in which the ionization device and sensor are installed.

The pipe management system 400 may be configured to include a water pipe 22 having two or more outlets. Referring to FIG. 4 , the pipe management system 400 may be configured to include at least a portion of the water pipe 21 of the pipe management system 200 shown in FIG. 2 .

Referring to FIG. 4, the plumbing management system 400 includes a first outlet connected to a house (e.g., a third location of the water pipe 21), a second outlet connected to a building, and a third outlet connected to another water pipe. A water pipe 22 may be configured.

At this time, water quality sensors 205, 207, and 209 may be configured inside the water pipes of the first outlet, the second outlet, and the third outlet, respectively. For example, a third water quality sensor 205 may be configured at the location of the first outlet, a fourth water quality sensor 207 may be configured at the location of the second outlet, and a fifth water quality sensor 209 may be configured at the location of the third outlet. there is.

In addition, the water pipe 22 of the piping management system 400 in FIG. 4 is shown to include one ionization device 211, but is not limited to this and may further include at least one ionization device (not shown). It can be configured to include.

For example, the water pipe 22 further includes at least one ionization device between the second location (e.g., the location of the water quality sensor 203) and the third outlet, and/or between the second location and the third outlet. It can be configured to include.

When cleaning the inside of a water pipe in relation to the water quality of a specific location, the management device 100 may clean the pipe by operating an ionization device and/or a pipe cleaning device configured at the shortest distance from the inlet to the specific location.

For example, with an ionizer (A) additionally installed at location A between the second location (e.g., the location of the water quality sensor 203) and the fifth outlet, the water quality at the location of the fifth water quality sensor 209 and In relation to this, when cleaning the inside of the water pipe, the management device 100 operates the ionization device 211 and the ionization device (A) configured at the shortest distance between the inlet and the third outlet to clean the inside of the water pipe. .

On the other hand, when cleaning the inside of the water pipe in relation to the water quality at the location of the fourth water quality sensor 207, the management device 100 operates the ionization device 211 configured at the shortest distance between the inlet and the second outlet to The inside can be washed.

The piping management system 400 may be configured to include a plurality of water quality management device sets. According to one embodiment, as shown in FIG. 2, one water quality management device set can be configured including a water quality sensor included in one inlet and one outlet, and one ionization device.

In more detail, it may be comprised of one water quality management set including a sensor, an ionizer, and a pipe cleaning device included in the shortest distance from the inlet to the outlet of the water pipe.

Referring to FIG. 4, the first water quality sensor 201, the ionizer 211, the second water quality sensor 203, and the third water quality sensor included in the water pipe constituting the shortest distance between the inlet and the house 23. The sensor 205 can be configured as a first set of water quality management devices.

In addition, the first water quality sensor 201, the ionizer 211, the second water quality sensor 203, and the fourth water quality sensor 207 included in the water pipe constituting the shortest distance between the inlet and the building 25. Can be composed of a second water quality management device set.

Additionally, a first water quality sensor 201, an ionizer 211, a second water quality sensor 203, and a second water quality sensor included in the water pipe constituting the shortest distance between the inlet and another water pipe (e.g., the third outlet). 5 The water quality sensor 209 can be configured as a third water quality management device set.

The management device 100 can divide the areas of the water pipe 22 in units of three water quality management devices, and calculate the average of the water quality information values in units of three water quality management devices for each zone.

In addition, the management device 100 may calculate the average of the difference values of water quality information for each zone in units of three water quality management devices.

Referring to FIGS. 2 and 4, the piping management system is described with respect to water pipes 21 and 22 having one inlet, but the system is not limited thereto and may be configured to include water pipes having two or more inlets. .

At this time, when explaining the operation of a water pipe having a plurality of inlets, the management device 100 may perform the pipe management operation through the same or similar method as that of the water pipe 22 having a plurality of outlets.

According to various embodiments, the management device 100 may provide a control algorithm for efficiently operating the heat exchanger piping of a building in a specific target based on acquired information.

For example, the management device 100 measures at least some of the conditions of the water quality, temperature, flow rate, and pressure of the heat generator portion and piping of the heat exchanger through the ionizer and sensor installed at the starting point of the heat exchanger and the heat exchanger and Algorithms for controlling the flow of pipes can be provided.

For example, when operating the ionization device through step 305(c) of FIG. 3, the management device 100 may control the flow rate of the fluid based on the water quality of the water pipe, the temperature of the fluid, and the flow rate of the fluid. there is.

For example, when cleaning the inside of the pipe through the ionization device 211, the management device 100 maintains a specified fluid speed for the water quality, fluid temperature, and operation level of the ionization device 211. 21) The internal flow rate can be controlled.

In addition, the management device 100 predicts the replacement time of piping and related equipment and provides information about this (e.g., notification message) to the display unit and/or the manager device, thereby creating an environment for building a smart factory. can be configured.

According to various embodiments, the management device 100 obtains at least some information among water usage, water leakage, vibration, turbidity, salinity, heavy metals, water temperature, and other water quality changes in homes and/or buildings, and based on this, the village or It is possible to obtain and/or predict at least some information among water usage, water leakage, vibration, turbidity, salinity, heavy metals, water temperature, and other water quality changes in an expanded range such as in cities.

The management device 100 can determine the amount of water produced and the amount of water consumed based on acquired and/or predicted information, and can generate and provide standard data for determining the amount of water produced in the country. .

According to various embodiments, the management device 100 and the piping management system utilize an ionizer, a water quality and vibration sensor device that suppresses corrosion of building water pipes, and various public API information to determine an efficient use method of tap water and piping. Management skills can be improved.

According to the above, a management device 100 and a pipe management system may be provided on a village and/or city basis, and the management device 100 may monitor the pipe status and water quality of pipes in the corresponding range through the pipe management system. Information can be obtained.

Through this, the management device 100 can build a database to provide basis data (standard data) for controlling the production of tap water, which is produced by more than 15% every year nationally.

According to the detailed description of the present invention, the management device 100 and the pipe management system manage the condition and water quality of the pipes to effectively reduce unnecessarily produced or wasted water resources, thereby reducing energy and carbon emissions generated when producing tap water. It has the effect of doing so.

According to the detailed description of the present invention, the functions of various embodiments described as being performed by the management device 100 are operations processed through the processing unit 110 of the management device 100 and/or the management device 100. It can be performed by being organically connected to the components of the device connected to (100).

As described above, although the embodiments have been described with limited drawings, those skilled in the art can apply various technical modifications and variations based on the above.

For example, the described techniques are performed in a different order than the described method, and/or components of the described system, structure, device, circuit, etc. are combined or combined in a different form than the described method, or other components are used. Alternatively, appropriate results may be achieved even if substituted or substituted by an equivalent.

Therefore, other implementations, other embodiments, and things equivalent to the claims should also fall within the scope of the claims described below.

100: Management device
110: processing unit
120: storage unit
130: Department of Communications
140: input/output unit

Claims (8)

In the operating method of a management device that manages fluid pipes using an ionization device,
In a fluid pipe comprised of an inlet and an outlet, a water quality sensor is configured inside the fluid pipe at each of sequentially set first positions, second positions, and third positions, and is located between the first position and the second position. With the ionization device configured inside the fluid pipe at the set fourth position,
(a) receiving sensing data from at least some of the water quality sensors configured at the first location, the second location, and the third location, and based on the sensing data, the first location, the second location, and Obtaining first water quality measurement information at a first time for each of the third locations;
(b) Future information for each of the first location, the second location, and the third location based on the sensing data, the first water quality measurement information, and the previously predicted first water quality prediction information at the first time point. determining second water quality prediction information at time 2; and
(c) operating the ionization device based on the first water quality measurement information and the second water quality prediction information,
The management device includes first situation information including waiting information, energy consumption information, and specific day information confirmed at the first time from at least one server connected to the management device, and waiting information predicted at the second time, Obtain second context information including energy consumption information and specific day information,
In step (b), the management device determines the second water quality prediction information by further considering the first situation information and the second situation information,
The atmospheric information includes weather, temperature, fog, precipitation, rainfall, season, solar environment, ozone, ultraviolet rays, magnetic field, fine dust, carbon dioxide, and carbon monoxide information,
The energy consumption information includes power usage, gas usage, water usage, coal usage at power plants, oil usage, water usage, and nuclear energy usage information,
The specific date information includes year, month, day, day of the week, anniversary, holiday, and public holiday information,
The management device is,
With the water quality exceeding the limit value divided into a plurality of levels, when the water quality exceeding the limit value exceeds a specific level, at least one bubble generator that generates bubbles in the direction of the outlet after the ionization device and at least one device that generates a vortex A method of operating a management device that manages fluid pipes using an ionization device that operates together with a pipe cleaning device consisting of a vortex generator.
◈Claim 2 was abandoned upon payment of the setup registration fee.◈ According to paragraph 1,
The management device, based on the first water quality measurement information and the second water quality prediction information, is configured to control the fluid at the first time point and the second time point at each of the first location, the second location, and the third location. A method of operating a management device for managing a fluid pipe using an ionization device that determines the internal state of the pipe and changes in the internal state of the fluid pipe.
◈Claim 3 was abandoned upon payment of the setup registration fee.◈ According to paragraph 1,
The management device includes first situation information including at least some of standby information, energy consumption information, and specific day information confirmed at the first time point from at least one server connected to the management device and predicted at the second time point. Obtain second situation information including at least some of standby information, energy consumption information, and specific day information,
In step (b), the management device determines the second water quality prediction information by further considering the first situation information and the second situation information. How it works.
◈Claim 4 was abandoned upon payment of the setup registration fee.◈ According to paragraph 1,
When operating the ionization device in step (c), the management device operates the ionization device based on the first water quality measurement information, the second water quality prediction information, and the flow rate measured for the fluid inside the fluid pipe. A method of operating a management device that manages a fluid pipe using an ionization device that adjusts the degree of ionization of the fluid.
◈Claim 5 was abandoned upon payment of the setup registration fee.◈ According to paragraph 4,
The management device controls the flow rate of the fluid based on the water quality of the fluid pipe, the temperature of the fluid, and the flow rate of the fluid. A method of operating a management device for managing a fluid pipe using an ionization device.
◈Claim 6 was abandoned upon payment of the setup registration fee.◈ According to paragraph 3,
The second water quality prediction information is situation information about a plurality of specific times in the past. It is determined based on an algorithm set to calculate water quality prediction information for situational information at a specific point in the future based on water quality measurement information and water quality prediction information,
The management device is,
After the second time point, the fluid pipe is managed using an ionization device that resets the algorithm based on the second water quality prediction information predicted at the second time point and the second water quality measurement information measured at the second time point. How the management device operates.
◈Claim 7 was abandoned upon payment of the setup registration fee.◈ According to paragraph 1,
The management device determines the location and amount of water leakage based on the sensing data and flow rates measured for the fluid inside the fluid pipe at each of the first location, the second location, and the third location,
Obtaining vibration information measured through a vibration sensor installed at at least a portion of the pipe,
In step (b), the management device determines the second water quality prediction information by further considering the location and amount of water leakage and the vibration information, and manages the fluid pipe using an ionization device. How it works.
◈Claim 8 was abandoned upon payment of the setup registration fee.◈ In a management device that manages fluid piping using an ionization device,
In a fluid pipe comprised of an inlet and an outlet, a water quality sensor is configured inside the fluid pipe at each of sequentially set first positions, second positions, and third positions, and is located between the first position and the second position. With the ionization device configured inside the fluid pipe at the set fourth position,
a communication unit connected to at least one sensor included in the water quality sensors configured at the first location, the second location, and the third location, and the ionization device; and
Receive sensing data from at least some of the water quality sensors configured at the first location, the second location, and the third location, and respectively detect the first location, the second location, and the third location based on the sensing data. Obtain first water quality measurement information at a first time point, and based on the sensing data, the first water quality measurement information, and the predicted first water quality prediction information at the first time point, the first location, the second A processing unit that determines a location and second water quality prediction information at a second time in the future for each of the third locations, and operates the ionization device based on the first water quality measurement information and the second water quality prediction information. Contains ;,
The management device includes first situation information including waiting information, energy consumption information, and specific day information confirmed at the first time from at least one server connected to the management device, and waiting information predicted at the second time, Obtain second context information including energy consumption information and specific day information,
The management device determines the second water quality prediction information by further considering the first situation information and the second situation information,
The atmospheric information includes weather, temperature, fog, precipitation, rainfall, season, solar environment, ozone, ultraviolet rays, magnetic field, fine dust, carbon dioxide, and carbon monoxide information,
The energy consumption information includes power usage, gas usage, water usage, coal usage at power plants, oil usage, water usage, and nuclear energy usage information,
The specific date information includes year, month, day, day of the week, anniversary, holiday, and public holiday information,
The management device is,
In a state where the water quality exceeding the limit value is divided into a plurality of levels, when the water quality exceeding the limit value exceeds a specific level, at least one bubble generator that generates bubbles in the direction of the outlet after the ionization device and at least one device that generates a vortex A management device for managing fluid pipes using an ionization device, further comprising a pipe cleaning device comprised of a vortex generator.