KR20230057505A - System for water pressure sensing using IoT - Google Patents

Abstract

A smart water pressure system using IoT according to the present invention includes: a smart water pressure gauge that measures water pressure in the pipes of each household and transmits the measured water pressure information through wireless communication; a repeater that connects the water pressure information transmitted from the smart water pressure gauge to an Internet communication network or a public communication network; and a hydraulic system server that receives and manages the water pressure information through the repeater and transmits the water pressure information to a user PC or user mobile terminal. Therefore, it is possible to manage the water pressure information in real time.

Description

Smart water pressure system using IoT {System for water pressure sensing using IoT}

The present invention relates to a smart water pressure system using IoT.

BACKGROUND ART In general, water supply facilities are provided in homes or various buildings to receive water. Waterworks facilities draw river water from a waterworks treatment plant, treat it at a water purification facility, and supply it to each household or consumer via a drainage facility. As a result, a lot of energy and cost are required in the process of water purification facilities, drainage and supply.

Such water supply facilities must have no leaks in the pipeline and must be supplied at an appropriate water pressure. In particular, when constructing a large-scale housing such as an apartment building, many pipes are built inside, and if water leakage is not managed in the beginning, secondary water leakage damage may occur. Therefore, when constructing or managing a building, a water pressure gauge must be installed in the piping to check for leaks in the piping. It is difficult to supply water with normal water pressure to high floors with only the water pressure supplied from the water purification plant. In high-rise buildings such as apartments, pressurized pumps are used for each building to supply water to each household while always applying an appropriate pressure to the water pipe. When the pressure pump drops below the water pressure set through the sensor, the pump operates to keep the pressure constant.

In addition, the operating pressure and allowable pressure of the pipe are set for each section according to the height of each building and the type of pipe. In order to determine whether there is a leak in the pipe during construction, an appropriate pressure is set for each route, and the leak is judged according to the degree of pressure drop. In addition, management is also carried out so that the pressure does not exceed the allowable pressure of each pipe in an overpressure state.

Currently, when constructing an apartment, water pressure is checked by installing a water pressure gauge on each pipe by manpower, but it is experiencing difficulties due to cost increase due to labor cost and shortage of manpower. The reliability of the record is low, and there are problems in that it is difficult to find immediately when a leak occurs after measurement. In addition, it is difficult to utilize continuous water pressure change data.

At the apartment construction site, the number of households that can be inspected and recorded per person per day is about 300, and the efficiency of water pressure inspection is low. In addition, there is a problem in that continuous monitoring is impossible because even if each household is inspected every day, it is stopped at about once a day. In addition, there is a problem in that the efficiency of the hydraulic pressure check is low in the absence of a person who is familiar with the geographical characteristics of the construction site and the route of the pipe. Korean Registered Patent No. 10-0401482 relates to a leak detection connection device for underground water pipelines by installing a leak monitoring sensor and a protective jacket at the joint of the water pipeline to remotely check whether or not there is water leakage at the joint of the water pipeline in real time. A method of detection is proposed. Korean Patent Registration No. 10-0401482 is only for detecting water leaks at the joints of water pipelines, and does not provide a technology for systematically sensing the water pressure of all pipes in an apartment building in the early stage of construction.

Republic of Korea Patent Publication No. 10-0401482 (Leak detection connection device for underground water pipe)

An object of the present invention is to provide a smart water pressure system using IoT that can easily measure water pressure in pipes of complex residential facilities using a portable wireless smart water pressure gauge with low power and manage water pressure information in real time.

According to one aspect of the present invention, a smart water pressure system using IoT includes a smart water pressure gauge for measuring water pressure in a pipe of each household and transmitting the measured water pressure information through wireless communication; a repeater connecting the water pressure information transmitted from the smart water pressure gauge to an internet communication network or a public communication network; and a water pressure system server receiving and managing the water pressure information from the repeater and transmitting the water pressure information to a user PC or user mobile terminal.

In addition, the wireless communication is characterized in that the 917.1 ~ 923.3MHz frequency band LoRa technology based LPWA communication or mobile communication LTE communication.

In addition, the smart water pressure gauge includes a water pressure sensor connection socket formed on one side of the outer case to connect to the pipe; a water pressure sensor unit connected to the connection socket to generate a sensing signal for water pressure; a control unit for controlling the operation of each unit; an interface unit for mutually connecting the water pressure information sensed by the water pressure sensor unit to a communication module to enable transmission using a communication protocol; and a communication module for communicating to transmit or receive the water pressure information according to a communication protocol. It is characterized in that it includes.

In addition, the smart water pressure gauge may include a slave smart water pressure gauge that measures water pressure in pipes installed in one or more pipes in each household and transmits the measured water pressure information through first LAN wireless communication; Master smart for measuring the water pressure in one pipe in each household and transmitting the water pressure information transmitted from the slave smart water pressure gauge through the first LAN wireless communication and the measured water pressure information to the repeater through second LAN wireless communication Characterized in that it includes a water pressure gauge.

In addition, the first LAN wireless communication is ZigBee communication, and the second LAN wireless communication is characterized in that LPWA (Low Power Wide Area) communication.

In addition, the smart water pressure gauge is characterized in that water pressure information is transmitted in a state of current water pressure measurement or periodic water pressure measurement according to a switching signal of the input unit.

In addition, the communication module is a built-in antenna type and includes a first LAN wireless communication module and a second LAN wireless communication module, and selectively applies transmission and reception of the first or second short-range wireless communication by switching the input unit. characterized by

In addition, the control unit is characterized in that an MCU or a microcomputer.

In addition, the water pressure sensor connection socket is characterized in that it is formed as a threaded socket in which a thread is formed to be screwed into a pipe.

In addition, the smart water pressure gauge may further include an input unit through which a user's control signal is input and an output unit through which state information or measurement information of the smart water pressure gauge is output.

In addition, the input unit is characterized in that it includes any one or more of a sliding switch, a push button switch or an external input terminal.

In addition, the water pressure system server is characterized in that it receives the water pressure information and transmits it to the user's PC or the user's mobile terminal through a user app.

In addition, the water pressure system server is characterized in that it transmits an emergency warning signal and a water pressure state to a mobile terminal of a user or person concerned when the water pressure falls below a predetermined standard from the transmitted water pressure information.

In addition, the water pressure system server transmits information on the water pressure measurement time, water pressure status, water pressure change status, power status and current operating status for each household pipe to the user's PC or the user's mobile terminal through the user app. characterized by

In addition, the user is characterized in that the user remotely controls an operating state such as water pressure measurement and stop for the smart water pressure gauge installed through the user app.

According to an embodiment of the present invention, during the construction of large-scale apartments, it can be easily measured using a wireless smart water pressure gauge, and water pressure information can be managed in real time with minimal power consumption or battery with a low-power communication system.

The smart water pressure system according to an embodiment of the present invention can effectively identify and manage water pressure measurement time, water pressure status, water pressure change status, power status, and current operating status for each household pipe.

In addition, the on-site water pressure manager can selectively visit and treat only the pipes of households for which the water pressure is determined to be abnormal, thereby increasing the work efficiency of water pressure personnel.

In addition, it can be monitored in real time through a mobile app, and when the water pressure is below or exceeds the appropriate setting range, a warning or an alarm is issued to the mobile terminal of the person concerned, so that problems can be quickly dealt with.

In addition, it is possible to improve the reliability according to the water pressure measurement compared to the data accumulation of the water pressure record and the conventional off-line measurement system.

In addition, when constructing a large-scale apartment, it is possible to grasp the water pressure condition for each pipe in real time from the site office, and it is possible to check multiple overlapping checks such as the person in charge of the construction company, the site manager, the foreman, and the supervisor, so that the reliability of monitoring can be increased.

1 is a communication schematic diagram of a smart water pressure system using IoT according to an embodiment of the present invention.
2 is a communication schematic diagram of a smart water pressure system using IoT based on an LTE network according to another embodiment of the present invention.
3 is a communication schematic diagram of a smart water pressure system using IoT using a slave-master water pressure gauge according to another embodiment of the present invention.
4 shows an example of a block diagram of a smart water pressure gauge according to an embodiment of the present invention.
5 illustrates an example of the appearance of a smart water pressure gauge according to an embodiment of the present invention.
6 to 10 illustrate examples in which water pressure information is output through a user app according to an embodiment of the present invention.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In the present application, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

In addition, terms such as "...unit", "...unit", "module", and "device" described in the specification mean a unit that processes at least one function or operation, which is hardware or software, or a combination of hardware and software. can be implemented as

Also, terms such as first and second may be used in describing components of an embodiment of the present invention. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being 'connected', 'coupled' or 'connected' to another element, the element may be directly connected, coupled or connected to the other element, but not between the element and the other element. It should be understood that another component may be 'connected', 'coupled' or 'connected' between elements.

Hereinafter, a smart water pressure system using IoT according to an implementation of the present invention will be described in detail.

The Internet of Things (IoT) refers to a technology or environment in which sensors are attached to objects and data is exchanged over the Internet in real time.

The present invention was conceived to improve water pressure inspection and management by developing a smart water pressure gauge based on Internet of Things (IoT).

1 is a communication schematic diagram of a smart water pressure system using IoT according to an embodiment of the present invention.

Referring to FIG. 1, the smart water pressure system using IoT according to an embodiment of the present invention measures the water pressure in the water pipe and transmits the measured water pressure information through wireless communication (S ₁₁ ~ _Sn ,) A repeater 110 that connects the water pressure information transmitted from the smart water pressure gauges (S ₁₁ to _Sn ) to an internet communication network or a public communication network, receives and manages the water pressure information from the repeater 110 through a public communication network or the Internet network, , and a water pressure system server 150 that transmits the water pressure information to the user PC 220 or the user mobile terminal 210.

According to an embodiment of the present invention, the user mobile terminal 210 may include any one or more of a smart phone, a tablet, and a PDA.

The repeater 110 according to an embodiment of the present invention is a router repeater applied to amplify a signal or connect a LAN and an Internet communication network or a public communication network.

Smart water pressure gauges (S ₁₁ to Sn ₎ according to an embodiment of the present invention are characterized in that they transmit information wirelessly while being low-powered small devices including a battery method to facilitate installation and good portability at a construction site. . In order to apply the portable wireless water pressure gauge to the field, the smart water pressure system according to an embodiment of the present invention was developed with an emphasis on minimizing power consumption in the smart water pressure gauge.

According to an embodiment of the present invention, the communication from the smart water pressure gauge (S ₁₁ to _Sn ) to the repeater 110 is LPWA (Low Power Wide Area) communication, Zigbee communication, Wi-Fi communication, LTE mobile communication It is characterized in that any one wireless communication technology is applied.

LPWA technology is characterized by low power consumption and long-distance coverage, and has advantages of security and low cost, so it can be applied as a communication method that is very suitable for IoT such as water pressure gauges. According to an embodiment of the present invention, communication from the smart water pressure gauge (S ₁₁ to Sn,) to the repeater 110 is performed using LTE-M or LoRa technology, or SUN (which consumes less power and requires relatively less cost) Smart Utility network) technology-based LPWA (Low Power Wide Area) communication can be applied.

In a preferred embodiment of the present invention, LTE Cat.M1 (National Commercial Network) technology using LoRa technology-based and licensed (800MHz, 1.8GHz) frequencies that have a long battery life and can use unlicensed bands (917.1 ~ 923.3MHz) frequencies It is characterized in that it is applied to LPWA communication of

In another embodiment of the present invention, since the communication distance is relatively long when the LoRa technology-based LPWA communication is applied, the relay 110 is omitted according to the location of the water pressure system server 150, and the base station or water pressure of the public communication network is directly A communication system for transmission to the system server 150 may be applied.

2 is a communication schematic diagram of a smart water pressure system using IoT based on an LTE network according to another embodiment of the present invention.

Referring to FIG. 2 , when LTE mobile communication is applied, the hydraulic pressure system server 150 or the repeater 110 may be omitted because a system of a mobile communication company is used.

3 is a communication schematic diagram of a smart water pressure system using IoT using a slave-master water pressure gauge according to another embodiment of the present invention.

In general, in each household, each pipe is formed in the kitchen equipment heating system, shower equipment, and bathroom equipment, and water pressure must be measured for all pipes during construction. The pipe interval of each household is ~10m, but the distance from the repeater in each building to the pipe is ~100m.

In the embodiment of FIG. 3, when the slave smart water pressure gauge transmits the water pressure information on the pipes of each household at low output, the master smart water pressure gauge in each household collects it and transmits it to the repeater 110 together with the water pressure information measured by itself. It is characterized by doing.

In this case, the slave smart water pressure gauge (S ₁₁ ~ _Sn ,) maintains only an output of a transmission distance of ~ 10 m, so it can communicate with a relatively small output, compared to the embodiment of FIG. 1, the slave smart water pressure gauge (S ₁₁ ~ S _n ,) power consumption can be reduced.

The smart water pressure system using the IoT according to FIG. 2 measures the water pressure in a water pressure gauge installed in one or more pipes in each household and transmits the measured water pressure information through first LAN wireless communication. ); Measuring the water pressure in one pipe in each household, and transmitting the water pressure information transmitted through the first LAN wireless communication from the slave smart water pressure gauge and the measured water pressure information to the repeater 110 through the second near LAN wireless communication Master smart water pressure gauge (M ₁ to M _n ); , and then the communication system is the same as that of FIG. 1 .

For example, one master smart water pressure gauge (M ₁ ) and a plurality of smart water pressure gauges (S ₁₁ to S ₁₆ ) are installed in the piping of each household of the apartment, and one repeater 110 is installed in each building of the apartment. Information transmitted from the master smart water pressure gauges (M ₁ to M _n ) may be transmitted to be connected to the water pressure system server 150 through an Internet communication network or a public communication network.

In a preferred embodiment of the present invention, the first short-distance LAN communication from each of the slave smart water pressure gauges (S11 to Sn,) to the master smart water pressure gauges (M1 to Mn) applies ZigBee communication with low power consumption, and the master smart water pressure The second LAN communication from the systems M1 to Mn to the repeater 110 may use Low Power Wide Area (LPWA) communication or an LTE communication network.

When the LTE communication network is applied, the water pressure system server 150 or the repeater 110 may be omitted as shown in FIG. 2 .

Referring to FIG. 3, each slave smart water pressure gauge (S ₁₁ to _Sn ,) transmits only water pressure information through ZigBee communication and receives it from the master smart water pressure gauge (M ₁ to M _n ) within ~20m, and each received The water pressure information of the pipe is transmitted from the master smart water pressure gauge (M ₁ to M _n ) to the repeater 110 through second LAN communication, so that a water pressure gauge is installed for each pipe to transmit the water pressure information to the repeater 110. Since power consumption can be reduced compared to the embodiment of FIG. 1 configured to transmit, there is an advantage in that the system can be configured most economically while reducing power consumption of each smart water pressure gauge.

Alternatively, both the first LAN wireless communication and the second LAN wireless communication may use ZigBee communication, which consumes less power and requires relatively less cost. In the case of normal ZigBee communication, the transmission distance is ~100m and the transmission speed is ~250kbps, so it is operated with the lowest power consumption to transmit the water pressure information of the smart water pressure gauge installed in the pipe of each household in the apartment building to the repeater 110. It can be.

Alternatively, when a transmission speed faster than the ZigBee communication is requested, the first LAN wireless communication and the second LAN wireless communication that transmits the water pressure information of the smart water pressure gauge installed in the pipe of each household to the repeater 110 in the apartment building are Wi-Fi It can be operated by applying -Fi communication or LPWA (Low Power Wide Area) communication.

According to an embodiment of the present invention, each slave smart water pressure gauge (S ₁₁ ~ _Sn ) and master smart water pressure gauge (M ₁ ~ M _n ) are assigned an ID, respectively, and are mounted on the pipe of the water pipe to be measured. .

4 shows an example of a block diagram of a smart water pressure gauge according to an embodiment of the present invention.

5 illustrates an example of the appearance of a smart water pressure gauge according to an embodiment of the present invention.

4 and 5, the smart water pressure gauge 10 according to an embodiment of the present invention is connected to a water pressure sensor connection socket 11 formed on one side of an outer case to connect to a pipe, and the connection socket 11 A water pressure sensor unit 12 that generates a sensing signal for water pressure, a control unit 15 that controls the operation of each unit, and a communication module to enable transmission of the water pressure information sensed by the water pressure sensor unit 12 using a communication protocol It includes an interface unit 17 that interconnects and a communication module 18 that communicates to transmit or receive the water pressure information according to a communication protocol.

According to an embodiment of the present invention, the controller 15 may be applied as a control MCU or a microcontroller (MICOM) including a CPU.

In addition, the smart water pressure gauge 10 according to an embodiment of the present invention includes an input unit 16 to which a user's control signal is input and an output unit 19 to output state information or measurement information of the smart water pressure gauge 10. can include more.

The input unit 16 may include any one or more of a sliding switch, a push button switch, or an external input terminal.

According to one embodiment of the present invention, the sliding switch can be used for power control, the push button switch can be used for operating state control, and the external input terminal can be used for inputting a control signal from the outside.

For example, power may be ON/OFF controlled by a sliding switch. In addition, a control signal may be input to a current water pressure check state or a periodic water pressure check state according to a push operation of the push button switch.

For example, if the push button is pushed once to check the current water pressure, the water pressure is measured for 250 ms, transmitted to the water pressure system server 150, and then controlled to be turned off.

In addition, when the push button is pushed a set number of times to switch to the periodic water pressure check state, the water pressure can be measured and transmitted to the water pressure system server 150 every period (eg, 1 to 10 minutes).

The output unit 12 according to an embodiment of the present invention may include any one or more of an LED lamp or a display.

For example, the LED lamp may be controlled to display whether or not power is supplied, a communication state, a failure state of a smart water pressure gauge, and the like. Alternatively, the display can be controlled to display the status and water pressure information of the smart water pressure gauge.

The communication module 18 according to an embodiment of the present invention includes a first short-range wireless communication module and a second short-range wireless communication module, and selects transmission and reception of the first or second short-range wireless communication by switching the input unit. It can be configured so that it can be applied as

Accordingly, one smart water pressure gauge can become a slave smart water pressure gauge that only transmits water pressure information to the master smart water pressure gauge by switching, or a master smart water pressure gauge that receives water pressure information from the slave smart water pressure gauge and transmits it to the repeater by switching again. can be applied sequentially.

The water pressure sensor connection socket 11 according to an embodiment of the present invention may be formed of a threaded socket for screwing into a pipe or a quick coupler type socket for coupling by detachably pushing into the pipe.

The water pressure system server 150 according to an embodiment of the present invention receives the water pressure information and transmits it to the user's PC or the user's mobile terminal through the user app.

A user according to an embodiment of the present invention may be an employee of a partner company, an employee of a construction company, or a person related to a construction site who has received approval for use from the hydraulic system server 150 .

The water pressure system server 150 according to an embodiment of the present invention may assign a unique ID to each household and each pipe, collect water pressure change data from the transmitted water pressure information, and transmit necessary information to the user.

In addition, when the water pressure falls below or exceeds a certain standard from the transmitted water pressure information, it is determined as water leakage, and an emergency warning signal and water pressure state are transmitted to the mobile terminal of the person concerned or the user.

In addition, the user can remotely control the operating state of the smart water pressure gauge installed through the user app, such as water pressure measurement and stop.

110: repeater
150: hydraulic system server
210: user terminal
220 PC
S ₁₁ to S _n : smart water pressure gauge
M ₁ ~ M _n : Master smart water pressure gauge

Claims (15)

In a smart water pressure system using IoT,
The smart water pressure system,
A smart water pressure gauge that measures water pressure in each generation of pipes and transmits the measured water pressure information through wireless communication;
a repeater connecting the water pressure information transmitted from the smart water pressure gauge to an internet communication network or a public communication network; and
A smart water pressure system comprising a water pressure system server that receives and manages the water pressure information through the repeater and transmits the water pressure information to a user PC or user mobile terminal. According to claim 1,
The wireless communication is a smart water pressure system, characterized in that the LoRa technology-based LPWA communication or mobile communication LTE communication in the 917.1 ~ 923.3 MHz frequency band. According to claim 1,
The smart water pressure gauge includes a water pressure sensor connection socket formed on one side of the outer case to connect to the pipe;
a water pressure sensor unit connected to the connection socket to generate a sensing signal for water pressure;
a control unit for controlling the operation of each unit;
an interface unit interconnected with a communication module to enable transmission of the water pressure information sensed by the water pressure sensor unit using a communication protocol; and
a communication module for communicating to transmit or receive the water pressure information according to a communication protocol; Smart water pressure system comprising a. According to claim 1,
The smart water pressure gauge,
a slave smart water pressure gauge measuring water pressure in one or more pipes installed in each of the households and transmitting the measured water pressure information through first LAN wireless communication;
Master smart for measuring the water pressure in one pipe in each household and transmitting the water pressure information transmitted from the slave smart water pressure gauge through the first LAN wireless communication and the measured water pressure information to the repeater through second LAN wireless communication A smart water pressure system comprising a water pressure gauge. According to claim 4,
The smart water pressure system, characterized in that the first LAN wireless communication is Zigbee communication, and the second LAN wireless communication is LPWA (Low Power Wide Area) communication. According to claim 3,
The smart water pressure system transmits water pressure information in a state of current water pressure measurement or periodic water pressure measurement by a switching signal of the input unit. According to claim 3,
The communication module is a built-in antenna type and includes a first LAN wireless communication module and a second LAN wireless communication module, and selectively applies transmission and reception of the first or second short-range wireless communication by switching the input unit. smart water pressure system. According to claim 3,
The control unit is an MCU or a smart water pressure system, characterized in that the microcomputer. According to claim 3,
The water pressure sensor connection socket is a smart water pressure system, characterized in that formed of a screw-type socket with a thread to screw with the pipe. According to claim 3,
The smart water pressure gauge
The smart water pressure system further comprising an input unit through which a user's control signal is input and an output unit through which state information or measurement information of the smart water pressure gauge is output. According to claim 10,
The input unit,
A smart water pressure system comprising at least one of a sliding switch, a push button switch, or an external input terminal. According to claim 1,
The water pressure system server receives the water pressure information and transmits it to the user's PC or the user's mobile terminal through an app for the user. According to claim 12,
The water pressure system server transmits an emergency warning signal and a water pressure state to a mobile terminal of a user or person concerned when the water pressure falls below a certain standard from the transmitted water pressure information. According to claim 12,
The water pressure system server transmits information on the water pressure measurement time, water pressure status, water pressure fluctuation status, power status, and current operating status for each pipe for each household to the user's PC or the user's mobile terminal through the user app. smart water pressure system. According to claim 12,
The smart water pressure system, characterized in that the user remotely controls the operating state such as water pressure measurement and stop for the smart water pressure gauge installed through the user app.

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