KR20220011545A - Water and sewage monitoring system - Google Patents

Abstract

The present invention relates to a water supply and sewage monitoring system controlling a water supply and sewage system. The monitoring system comprises: a manager terminal managing the water supply and sewage monitoring system; a water supply detection sensor provided in a water supply system supplying water to a facility and deriving water supply system information; a sewage detection sensor provided in a sewage system transferring wastewater emitted from the facility and deriving sewage system information; and a water supply and sewage managing server receiving information derived from the water supply and sewage detection sensors to be stored in a database, transmitting the information to a manager terminal, and controlling the water supply and sewage system.

Description

Water and sewage monitoring system {Water and sewage monitoring system}

The present invention relates to a water supply and sewage monitoring system, and more particularly, by using an administrator terminal that manages the water supply and sewage monitoring system, and a water supply and sewage management server that controls water and sewage based on information derived from water and sewage, it is possible to easily control water and sewage. It relates to a water and sewage monitoring system.

In general, water flowing through tap water refers to water that has been purified for human consumption at a water purification plant by taking water from a water source.

In addition, the sewage flowing through the sewer refers to wastewater generated at each home or factory site, and was transferred to a sewage treatment facility for purification and disposal.

In addition, a plurality of flow junctions exist on a pipeline of water and sewage installed in a city or regional unit, and a valve for regulating the flow rate and a control device for controlling the same are installed at the flow junction on these pipelines. is being used

For example, technologies such as Korean Patent No. 10-09000717 "Remote control monitoring system and method for valve for water supply pipe" and Korean Patent No. 10-2104210 "Operation management and control system of water supply pipe" are disclosed. has been

However, in the control device, the manager who manages the facility cannot control it, the amount of water input to each facility and the amount of sewage generated from the facility are not constant, and the amount of consumption and discharge flow rate for each facility is not constant. Due to the difference from moment to moment, the manager who manages the facility cannot know information such as the pressure, flow rate, and inflow of water and sewage passing through the water and sewage pipes, so it is not easy to control the flow rate quickly and accurately.

In addition, the prior art lacks a device and a control device for measuring the degree of contamination of water flowing inside the water supply and sewerage pipe, so it is a factor that reduces the reliability of the supply of clean tap water, and amplifies distrust and anxiety about tap water in general households, etc. it has become

Therefore, there is an urgent need to develop a technology for a water supply and sewage monitoring system for monitoring the quality and quantity of water input to the facility and monitoring the amount of sewage discharged through the sewer system to easily manage it.

The present invention is proposed to solve the above problems, and the water and sewage monitoring system according to an embodiment of the present invention allows the manager to easily monitor and control the quality and quantity of water flowing in the water and sewage provided in the facility, and the amount of sewage. It aims to provide a water and sewage monitoring system that can do this.

In the water supply and sewage monitoring system for controlling water and sewage according to an embodiment of the present invention for solving the above problems, a manager terminal for managing the water and sewage monitoring system; a water supply detection sensor provided in the water supply that supplies water to the facility to derive information on the water supply; a sewage detection sensor provided in the sewer that transports sewage discharged from the facility to derive sewage information; It may include a water and sewage management server that receives the information derived from the water and sewage detection sensor and stores it in a database, transmits the information to the manager terminal, and controls the water and sewage.

In addition, the water supply detection sensor, the water supply flow rate detection sensor for monitoring the flow rate of water in the water supply; A water supply flow rate sensor for detecting the flow rate in the water supply; It may include a water supply water pressure measuring sensor for measuring the water pressure in the tap water and a tap water quality measuring sensor for measuring the water quality in the tap water.

In addition, the sewage detection sensor may include: a sewage flow rate detection sensor configured to monitor a flow rate of sewage flowing inside the sewage system; It may include a sewerage flow rate sensor for detecting the flow rate in the sewerage and a sewage water pressure measuring sensor for measuring the water pressure in the water supply.

In addition, the water supply and sewage management server includes a schedule setting module that allows and blocks water supply according to schedule setting information stored in the water supply and sewage management server through the manager terminal, and the schedule setting information includes month, date, It may be time-dependent control information.

In addition, the manager terminal may show the water and sewage information received through the water and sewage management server in a graph.

In addition, the water and sewage management server includes a water and sewage abnormality detection module, and the abnormal detection module includes flow rate, flow rate, water pressure, water quality information derived through the detection sensor and flow rate, flow rate, water pressure, When abnormality information is derived by comparing the water quality information, the details of the abnormality information may be transmitted to the manager terminal.

In addition, the water and sewage management server includes a water quality monitoring module and a sewage blocking module, and the water quality monitoring module is interlocked with the water quality measurement sensor. transmit, and the sewage blocking module may block the water supply in which the sewage details are detected.

In addition, the water and sewage monitoring system further includes a water leak detection module, wherein the water leak detection module is provided on the inner wall of the inlet in the direction in which water flows into the water supply and sewerage, a first measurement sensor for monitoring the inflow of water and sewage, and water into the water supply and sewerage system. It is provided on the inner wall of the discharge port in the discharge direction and includes a second measurement sensor for monitoring the discharge amount of water and sewage. When abnormal details occur in information derived from the first and second measurement sensors, the It can be transmitted to the manager terminal.

In addition, the water supply and sewage, a flow rate control diaphragm for controlling the flow rate of the constant and sewage flowing inside; A pressure control means for regulating the pressure inside the water and sewerage by opening and closing one side of the water and sewer according to the pressure inside the water and sewerage, and a guide pipe for guiding the water discharged from the water and sewage when one side of the water and sewage is opened by the pressure control means have.

The water and sewage monitoring system according to an embodiment of the present invention can remotely monitor and control water and sewage using a manager terminal, so that the manager can easily control water and sewage without going to the site.

In addition, through the monitoring sensor provided in the water supply and sewerage, when an abnormality occurs in the water supply and sewerage system, the administrator who manages the administrator terminal can immediately grasp the details of the abnormality, so that a quick response is possible.

In addition, the water supply and sewage monitoring system according to an embodiment of the present invention has the advantage of enabling more active water and sewage management by including a schedule setting module that can control water and sewage according to month, day, and time.

In addition, the water and sewage monitoring system according to an embodiment of the present invention includes a water leak detection module to easily detect water leaks occurring in water and sewage, and thus has the advantage of enabling quick follow-up actions.

1 is a configuration diagram showing the overall configuration of a water and sewage monitoring system according to an embodiment of the present invention.
Figure 2 is a schematic diagram for showing the flow of the water and sewage management system according to an embodiment of the present invention.
3 is an exemplary diagram for showing information displayed on a manager terminal according to an embodiment of the present invention.
4 is a block diagram showing the flow of a water and sewage monitoring system equipped with a sewage blocking module according to an embodiment of the present invention.
5 is an exemplary view for showing the state of the water supply and sewerage provided with a leak detection module according to an embodiment of the present invention.
6 is a perspective view illustrating the appearance of a water supply and sewage system provided with a flow control diaphragm, a pressure control means, and an induction pipe according to an embodiment of the present invention.
7 is an exemplary view for showing the internal configuration of a water supply and sewerage system according to an embodiment of the present invention.
8 is a cross-sectional view showing the inside of a water supply and sewerage system according to an embodiment of the present invention.
9 (a) and (b) are operational exemplary views for showing the operation of the flow control diaphragm according to an embodiment of the present invention.
10 (a) and (b) are operational exemplary views for showing the operation of the pressure control means according to an embodiment of the present invention.

Hereinafter, the description of the present invention with reference to the drawings is not limited to specific embodiments, and various modifications may be made and various embodiments may be provided. In addition, it should be understood that the contents described below include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention.

In the following description, terms such as 1st, 2nd, etc. are terms used to describe various components, meanings are not limited thereto, and are used only for the purpose of distinguishing one component from other components.

Like reference numbers used throughout this specification refer to like elements.

As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, terms such as "comprises", "comprises" or "have" described below are intended to designate the existence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification. It should be construed as not precluding the possibility of addition or existence of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

In addition, in the description with reference to the accompanying drawings, the same components are given the same reference numerals regardless of the reference numerals, and the overlapping description thereof will be omitted. In describing the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, the water and sewage monitoring system 1 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 10 .

First, FIG. 1 is a configuration diagram for showing the overall configuration of a water supply and sewage monitoring system according to an embodiment of the present invention, and FIG. 2 is a schematic diagram for showing a flow of a water supply and sewage management system according to an embodiment of the present invention, FIG. is an exemplary diagram for showing information displayed on the manager terminal according to an embodiment of the present invention.

1 to 3 , the water and sewage monitoring system 1 according to an embodiment of the present invention may include a manager terminal 100 , a detection sensor 200 , and a water and sewage management server 300 .

Specifically, the manager terminal 100 is provided to manage the water and sewage monitoring system 1 as a whole.

Here, the manager terminal 100 may be provided as an electronic device that the manager can carry, such as a smart phone, as shown in FIG. 1 , but this is only one illustrative example, and It may include any information processing device such as a PC or PDA for management.

In addition, the detection sensor 200P is provided in the pipe of the water supply P for supplying water to the facility M, and may derive information on water passing through the water service P.

Here, the detection sensor 200P may include a flow rate detection sensor 210P, a flow rate detection sensor 220P, a water pressure measurement sensor 230P, and a water quality measurement sensor 240P.

Specifically, the detection sensor 200P is preferably provided in the connection part of the water pipe P that is directly or indirectly connected to the facility M, and this is only a preferred embodiment, and the facility M that requires water supply (M) It may be provided inside (referred to as "a device or facility where water is used, such as a steam boiler or air conditioner," hereinafter referred to as a facility.").

In addition, the flow rate sensor (210P), the input and discharge from the water supply (P) The flow rate of the water supply can be monitored.

Specifically, as the flow rate sensor 210P, an electronic flow sensor or a flow meter using an ultrasonic method may be used, and the electronic flow sensor applies an appropriate voltage to the excitation coil to measure the flow rate and controls the flow of the fluid. It is a device that measures the flow rate by extracting a proportional induction signal, and the ultrasonic flow sensor can be a sensor that measures the flow of a fluid by generating a pulse wave ultrasonic wave and detecting a delay time according to the reception time proportional to the flow of the fluid. have.

This is provided to control the flow rate of water passing through the water supply (P) by transmitting the information to the water and sewage management server 300 when the amount of water input to the facility (M) is excessively excessive or low.

In addition, the flow rate sensor 220P, may monitor the flow rate of the water input and discharged from the water supply (P).

At this time, the flow rate sensor 220P may be provided to detect the flow rate of the water supply P, but may not be provided according to the setting of the administrator, and if the flow rate sensor 220P is not provided, the flow rate detection The flow rate in the water pipe may be measured based on the flow rate derived through the sensor 210P and the cross-sectional area of the pipe line of the water pipe P.

In addition, the water pressure measurement sensor 230P is provided to measure the water pressure of the water input and discharged from the water supply P, and is preferably provided on the inner upper side of the water pipe P, in the water pipe P. According to the height of the constant, it may be provided as a water pressure measuring sensor 230P for deriving information about water pressure, but this is only a preferred embodiment, and all types of sensors used to measure water pressure may be included.

In addition, the water quality measuring sensor 240P may measure the water quality of the water input and discharged from the tap water (P).

Specifically, the water quality measurement sensor 240P may be provided with a pH detection sensor for detecting the pH concentration of the constant flowing through the water pipe P or a Dissolved Oxygen (DO) sensor for detecting the amount of dissolved oxygen in the constant.

Accordingly, based on the information derived from the water quality measurement sensor 240P, the manager determines the quality of water input to the facility M and selectively controls the inflow of water through the water supply P with the control valve V This has the advantage of preventing deterioration due to corrosion of the facility M due to abnormalities in the pH and water quality of the water supply.

On the other hand, as the water quality measuring sensor 240P, an ultrasonic sensor capable of detecting suspended matter and turbidity may be used, which is only a preferred embodiment, and all sensors that can be used to measure water quality other than the ultrasonic sensor are may include

In addition, the detection sensor 200S for deriving the information of the sewage is provided in the pipe of the sewer S that transports the sewage generated from the facility M, and information about the sewage passing through the sewage S is derived. can do.

Here, the detection sensor 200S provided in the sewerage S may include a flow rate detection sensor 210S, a flow rate detection sensor 220S, and a water pressure measurement sensor 230S.

Specifically, the flow rate sensor 210S provided in the sewage system S is provided to monitor the amount of sewage discharged from the facility M, and the flow rate sensor 220S and the water pressure measurement sensor 230S are It is provided to monitor the load applied to the sewage (S) pipe in real time.

In addition, information derived from the flow rate sensor 210S, the flow rate sensor 220S, and the water pressure sensor 230S may be transmitted to and stored in the water and sewage management server 300 to be described later.

In addition, the water and sewage management server 300, based on the received information, regulates the flow of water flowing through the water and sewage (P, S) and interlocks with the control valve (V) provided in the water service (P) to manage water quality It is possible to control this, and by using the control valve (V) provided in the sewage (S), it is possible to control the discharge amount of sewage.

Specifically, the water and sewage management server 300 receives the data related to the information derived through the aforementioned flow rate, flow rate, water pressure, and water quality measurement sensors 210P, S to 230P, S and 240P, and the water and sewage management server The details may be stored in the database 310 provided in the 300 , and information about the details may be transmitted to the manager terminal 100 .

Here, as a means for communication between the manager terminal 100 and the water and sewage management server 300, a wireless communication network such as a wireless LAN, Bluetooth, or Wi-Fi may be used.

However, this is only a preferred embodiment, and may include all means for communication between the manager terminal 100 and the water and sewage management server 300 , and may communicate by wire in a situation where wireless communication is limited.

Here, the manager terminal 100 also receives information about the water supply (P) and the sewage (S), and is sensed by the detection sensors 200P and S in the storage module 110 provided in the manager terminal 100 information can be stored.

In addition, the manager terminal 100 and the water and sewage management server 300 may delete information stored in the database 310 and the storage module 110 in which information is stored.

This is due to the fact that when the amount of water used at night or on public holidays is not large and the discharge of sewage does not occur, unnecessary information on the water supply (P) or the sewage (S) is stored, so the database 310 of the water supply and sewage management server 300 ) and unnecessary information are accumulated in the storage module 110 of the manager terminal 100 to manage the problem that the storage space becomes narrow.

On the other hand, the manager terminal 100, the information about the flow rate, flow rate, water pressure, and water quality of the water supply transmitted through the water supply and sewage management server 300 may be shown in a graph (G) or in letters, numbers, and tables.

Referring to FIG. 3 as an example, the graph G may be displayed on the manager terminal 100 in a manner that shows information about a constant passing through the water supply P as a number, a bar type, or a line graph. .

Meanwhile, the sewage water passing through the sewer (S) may also be displayed on the manager terminal 100 in the same manner as the graph of the water supply (P).

In addition, the water and sewage management server 300 may also store the same information as the information about the graph (G) displayed on the manager terminal 100 in the database 310, and the manager terminal 100 is the water and sewage management server 300 When a graph G related to the stored water supply (P) and sewage (S) information is requested through the ) can be passed to

Accordingly, the manager possessing the manager terminal 100 has the advantage of being able to easily receive information related to water supply (P) and sewage (S) information, check it, and take follow-up actions.

In addition, the database 310 provided in the water supply and sewage management server 300 is the sensing information of the detection sensor regarding the water pipe (P) according to the facility (M) that requires water, that is, the flow rate, flow rate, water pressure, water quality detection. It is possible to store permission information on flow rate, flow rate, water pressure, and water quality transmitted from the sensors 210P to 240P, respectively, and sensing information of the detection sensor related to the sewage (S), that is, flow rate, flow rate, water pressure sensor (210S to 230P) It is possible to store permission information about flow rate, flow rate, and water pressure transmitted from each.

Here, the permission information may be set through the manager terminal 100 or the water and sewage management server 300, and refers to the allowable values for flow rate, flow rate, water pressure, and water quality to the water input to the facility M, The manager terminal 100 or the water and sewage management server 300 may control the control valve (V) provided in the water supply (P) pipe to maintain an allowable value to adjust the flow rate, flow rate, water pressure, and water quality of the water supply.

For example, when the water passing through the water supply (P) exceeds or falls short of allowable values related to flow rate, flow rate, water pressure, and water quality, the water and sewage management server 300 transmits the details to the manager terminal 100 By controlling the control valve (V) provided in the water supply (P), and to variably control the flow rate, flow rate, water pressure, and water quality of the water supply (P).

In addition, by adjusting the control valve (V), when the flow rate, flow rate, water pressure, and water quality in the water supply pipe (P) return within the allowable value range, the water supply and sewage management server 300 returns to the normal state of the water supply. By transmitting an alarm indicating that the return has been made to the manager terminal 100 and adjusting the control valve V again, it is possible to uniformly manage the water in the water supply pipe P.

On the other hand, the method of controlling the water supply (P) described above may be equally applied to the sewage (S).

As a result, the manager who manages the water supply (P) that is connected to the facility (M) and supplies water to the facility (M) through the water and sewage management server 300 that actively controls the state of the water and sewage (P, S), Stress related to management can be reduced and immediate response is possible, so it is possible to solve the outage of the facility (M) due to a problem occurring in the water pipe (P), and at the same time, it is possible to easily manage the sewage (S). have an advantage

In addition, the water and sewage management server 300 may include a schedule setting module 320 , a water and sewage abnormality detection module 330 , a water quality monitoring module 340 , and a sewage blocking module 350 .

First, the schedule setting module 320 is provided to control the constant flowing through the water supply P according to the month, date, and time.

Specifically, the schedule setting module 320 is a control valve ( V) is adjusted.

In addition, the pre-stored information may be transmitted to the water and sewage management server 300 by the administrator using the information according to the month, date, and time to the administrator terminal 100 .

Accordingly, the water and sewage management server 300 receives the data, and allows or blocks the water supply P by adjusting the control valve V provided in the water supply P based on the stored information.

In this case, the schedule setting module 320 may be linked with each facility M used for the water supply P, and set the amount of water used for each facility M by time.

Through this, by setting the supply of water through the water supply (P) to an appropriate time zone for each facility (M), it is possible to control the supply of water according to the purpose according to the facility (M) using the water supply (P).

For example, if the weather is hot in summer, when constant water is used for the purpose of cooling water for operating the air conditioner, the schedule setting module 320 maintains the allowed state in adjusting the amount of water input to the air conditioner, You can set the maximum permissible value of constant between 1 pm and 3 pm when it is hot, and since it is summer when the steam boiler is not used due to the hot weather, the water supplied to the boiler must be cut off.

In addition, when constant water is used for the purpose of operating a steam boiler in winter when the weather is cold, the schedule setting module 320 maintains an allowable state in adjusting the amount of water input to the boiler, but in the evening when the weather is cold It is possible to set the maximum allowable value of constant water from 6 am to 6 am the next day.

Accordingly, by blocking the water input to the unused facility (M), it is possible to continuously supply the water input to the mainly used facility (M) by hour, month, and date, so that easy resource management can be performed. have the advantage that

Next, the water and sewage abnormality detection module 330, based on the information derived through the above-described flow rate, flow rate, water pressure, and water quality sensor 240, detects whether there is an abnormality in the water supply flowing through the water supply (P), and sewage ( It is possible to detect whether there is an abnormality in the load of the sewage (S) according to the sewage flowing through S) and the amount of sewage.

Specifically, the information derived through the detection sensor 200 is compared with standard data of constant and sewage stored in the database 310 of the water and sewage management server 300, and when a difference value is generated compared to data, it is It is transmitted to the terminal 100 .

Here, the standard data refers to the average value of the constant flowing through the water supply (P) provided in the facility (M), and the average value is each of the flow rate, flow rate, water pressure, and water quality related to the constant stored in the database (310). I mean the average amount.

At the same time, the standard data refers to the average value of the sewage discharged on average from the facility M, that is, the average value of the sewage flowing through the sewer S, which is also related to the sewage stored in the database 310 described above. It refers to the average amount of each of the flow rate, flow velocity, and water pressure.

As a result, the manager in possession of the manager terminal 100 receives the information about the abnormality, and can immediately recognize that an abnormality has occurred in the water supply (P) and the sewer (S), and as a quick follow-up measure, Alternatively, it has the advantage of preventing damage such as a cutoff of constant water and reverse flow of sewage that may be generated in the facility M due to sewage.

In addition, the water quality monitoring module 340 and the sewage blocking module 350 will be described in detail with reference to FIG. 4 .

4 is a block diagram showing the flow of a water and sewage monitoring system equipped with a sewage blocking module according to an embodiment of the present invention.

First, the water quality monitoring module 340 is interlocked with the water quality measurement sensor 240 to transmit the details to the sewage blocking module 350 when the water pollution degree of the tap water P exceeds the allowable amount.

The sewage blocking module 350 that has received the details controls and blocks the control valve (V) provided in the water supply (P) through which the water from which the sewage details are detected flows, thereby preventing the sewage from flowing into the facility (M). can be blocked

On the other hand, the sewage blocking module 350, by controlling the control valve (V) as described above, can prevent sewage from flowing into the facility (M), but blocks the water supply (P) into which the sewage is introduced Before being put into the facility M, the inlet pipe 353 connected to the sewage storage tank 351 for storing the sewage water is provided as a sewage pipe 355 for sewage treatment, and the sewage is stored It is possible to store the sewage in the sewage storage tank (351).

In this case, the wastewater storage tank 351 may include a purification module 352, and according to the degree of contamination, the wastewater is discharged to the sewer (S) for disposal, or a chlorine input device provided for disinfection of the wastewater is used. After purifying the sewage by doing so, an inflow pipe 354 capable of introducing the purified sewage back into the facility M may be provided.

Accordingly, the water supply monitoring system 1 according to an embodiment of the present invention provided with the water quality monitoring module 340 and the sewage blocking module 350 blocks the input of sewage to the facility M, but to be purified and used. Sewage of acceptable water quality can be purified and used again for the facility M, which has the advantage of reducing the waste of water.

In addition, Figure 5 is an exemplary view for showing the state of the tap water provided with a leak detection module according to an embodiment of the present invention.

Referring to FIG. 5 , the water supply monitoring system 1 according to an embodiment of the present invention may further include a water leak detection module 400 for detecting water leakage in the water supply P or sewer S pipe.

In addition, the leak detection module 400 may include a first measurement sensor 410 and a second measurement sensor 420 , and a GPS module 430 . (At this time, the leak detection module 400 is equally applicable to the water supply (P) and the sewage (S), and for convenience of explanation, the embodiment of the water supply (P) will be applied and described.)

Specifically, the first measurement sensor 410 is provided on the inner wall or outer wall of the inlet in the direction in which water flows into the pipe of the water supply P, and measures the flow rate flowing into the water supply P, and the water leak detection module ( 400) to transmit information about the inflow flow rate.

In addition, the second measurement sensor 420 is provided on the inner wall of the discharge port in the direction in which water is discharged to the water supply P, and measures the flow rate discharged from the water supply P, and the discharge flow rate to the water leak detection module 400 transmit information about

If an abnormality occurs in the water quantity information derived from the first measurement sensor 410 and the second measurement sensor 420 by the water leak detection module 400, the information is transmitted to the manager terminal 100 can

In addition, the first measurement sensor 410 and the second measurement sensor 420 is provided in the water supply pipe (P), the GPS module 430 is provided, the location information about the water supply (P) manager terminal 100 ) or may be transmitted to the water and sewage management server 300 .

This is to easily determine the location of the water supply P where the leak has occurred.

Here, the location of the water supply (P) transmitted to the manager terminal 100 through the GPS module 430 is interlocked with the GPS 120 provided in the manager terminal 100 itself, and the manager terminal 100 and Information that can be derived from the location, such as information on the distance from which the water supply (P) has fallen, the way to go, the time required for moving, etc. may be displayed on the manager terminal 100 .

Finally, Figure 6 is a perspective view for showing the appearance of the water supply provided with the flow control diaphragm, the pressure control means and the guide pipe according to the embodiment of the present invention, Figure 7 is the internal configuration of the water supply and sewerage according to the embodiment of the present invention 8 is a cross-sectional view for showing the inside of a water supply and sewage system according to an embodiment of the present invention, and FIGS. 9 (a) and (b) are flow control diaphragms according to an embodiment of the present invention It is an exemplary operation view for showing the operation of, FIGS. 10 (a) and (b) are operational exemplary diagrams for showing the operation of the pressure control means according to an embodiment of the present invention.

6 to 10, the water supply (P) or the sewage (S) provided in the water supply monitoring system 1 according to an embodiment of the present invention, the flow control diaphragm 500, the pressure control means 600 and It may include a guide tube 700 .

First, the flow control diaphragm 500 is provided inside the water supply (P) or the sewage (S), preferably, as shown in FIGS. 8 and 9, the center of the water supply (P) or the sewage (S) It forms an angle of 120 degrees as a reference and may be provided in three plurality.

However, this is only a preferred embodiment, and may be transformed into a flow control diaphragm having an appropriate angle according to a user's request and provided with one to two or a plurality of four or more.

In addition, when the flow control diaphragm 500 is provided in the water supply P, it may be formed of a material that does not rust so as not to affect the quality of the water flowing inside the water supply P.

In addition, the flow control diaphragm 500 may be formed of a material that can easily withstand the pressure generated from water and sewage flowing through the water supply (P) or the sewage (S), for example, stainless steel having an appropriate strength It may be formed of a material.

In addition, the flow control diaphragm 500 is most preferably formed in a shape corresponding to the inner arc shape of the water supply (P) or the sewage (S) having a cylindrical shape.

This is, when the flow control diaphragm 500 completely opens the water supply (P), the water flowing through the inside of the water supply (P) interferes with the constant due to the flow control diaphragm 500 and is non-uniformly supplied to the facility (M) in order to solve the problem.

In addition, the flow control diaphragm 500 may be operated by a rotation motor 510 as shown in FIG. 8 , but this is only a preferred embodiment, and the flow control diaphragm 500 is connected to the water supply (P) and the sewage ( It may include all mechanical devices capable of rotating inside S).

In addition, the flow control diaphragm 500 may be operated based on information about the flow rate among information derived from the water supply (P) or the sewage (S).

To explain an operation example, if there is no abnormality in the flow information of the water supply (P) and the sewage (S) derived through the detection sensor 200, the flow control diaphragm 500 is maintained as shown in FIG. 9 (b) When the amount of water and sewage passing through the water supply (P) or the sewage (S) is too large, the flow control diaphragm 500 is adjusted as shown in FIG. It is to reduce the flow rate passing through the sewer (S).

In addition, the pressure control means 600, by partially opening the side of the water supply (P) or the sewage (S) according to the pressure inside the water supply (P) or the sewage (S) to adjust the pressure inside the water supply (P) can be provided for.

Specifically, the pressure control means 600 is provided so as to surround the circumference of the water supply (P) or the sewage (S), a cover 610 having an outlet hole 620 through which water is discharged, the cover 610 . It may include a rotation motor 630 for rotating the.

In addition, the cover 610 has a gear tooth 611 that can engage with a gear tooth 631 extending from the end of the rotation motor 630 is formed on the surface, and the water supply ( P) or it can rotate around the sewer (S).

On the other hand, the outlet hole 621 may be formed in the water supply (P) or the sewage (S), and the number and spacing corresponding to the outlet hole (620).

In addition, the pressure control means 600, the operation can be controlled in conjunction with the sensor 200 for deriving information on the water supply (P) and the sewage (S).

To explain an operation example, if there is no abnormality in the pressure information of the water supply (P) and the sewage (S) derived through the detection sensor 200, the pressure control means 600 is closed as shown in (a) of FIG. When the pressure of the water supply (P) or the sewage (S) derived through the detection sensor 200 increases, the pressure control means 600 is adjusted as shown in FIG. , By matching the positions of the outlet hole 620 formed in the cover 610 and the outlet hole 621 formed in the water supply (P) or the sewage (S), the constant flowing inside the water supply (P) or the sewage (S) Alternatively, by discharging the sewage to the outside, it is possible to prevent excessive pressure from being formed inside the water supply (P) and the sewage (S).

In addition, as described above, the water flowing out of the water supply P may be discharged to the outside through the guide pipe 700 shown in FIGS. 6 and 7 .

This is to prevent a problem in the fixing power of the water supply (P) from occurring because the ground covering the water supply (P) holds water when the water is discharged to the outside of the water supply (P) buried underground.

In addition, the sewage discharged through the guide pipe 700 may also be connected to the sewage pipe S of normal pressure instead of the sewage pipe S in which excessive pressure is generated to discharge the sewage.

In addition, on the outside of the pressure control means 600, a guide pipe 700 is provided to induce the outflow of water, and the rotation that was exposed to the outside of the pressure control means 600 and the water and sewerage (P, S) described above. A housing H surrounding the motors 510 and 630 may be provided.

At this time, the housing (H) may be provided with a space (H-1) in which the rotary motor is provided and a space (H-2) in which the constant flowing out from the above-described outlet holes (620, 621) is temporarily stored. have.

This is to solve the problem that, when the housing (H) is formed to have only one space, water intrudes into the rotation motors 510 and 630 provided inside the housing (H) and is damaged in an impossible state. to be.

On the other hand, the water flowing into the guide pipe 700 may be discharged to the aforementioned sewage pipe (S) or stored in a storage tank separately provided to store the water.

The embodiment of the present invention described above is not implemented only through an apparatus and/or method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium in which the program is recorded, etc. Also, such an implementation can be easily implemented by those skilled in the art to which the present invention pertains from the description of the above-described embodiments.

In addition, although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also presented. It belongs to the scope of the invention.

1: Water and sewage monitoring system
100: administrator terminal
110: storage module
120: GPS module provided in the manager terminal
200: detection sensor
210: flow detection sensor
220: flow rate sensor
230: water pressure measuring sensor
240: water quality measurement sensor
300: water and sewage management server
310: database
320: schedule setting module
330: water and sewage abnormality detection module
340: water quality monitoring module
350: sewage blocking module
351: sewage storage tank
352: purification module
353: inlet pipe where sewage water enters
354: discharge pipe through which purified water enters the facility
355: a discharge pipe for discharging sewage water to the sewer pipe
400: leak detection module
410: first measurement sensor
420: second measurement sensor
430: GPS module provided in the leak detection module
500: flow control diaphragm
510: flow control diaphragm rotation motor
600: pressure control means
610: cover
611: gear tooth
620: spill hole
621: water supply outlet
630: pressure control means rotation motor
640: gear tooth
700: guide tube
G: graph
P: water supply
V: control valve
M : facility
S: sewer
H: housing

Claims (9)

In the water and sewage monitoring system for controlling water and sewage,
a manager terminal for managing a water and sewage monitoring system;
a water supply detection sensor provided in the water supply that supplies water to the facility to derive information on the water supply;
a sewage detection sensor provided in the sewer that transports sewage discharged from the facility to derive sewage information;
Water and sewage monitoring system, characterized in that it receives the information derived from the water and sewage detection sensor, stores it in a database, transmits the information to the manager terminal, and includes a water and sewage management server that controls water and sewage.
The method of claim 1,
The water supply sensor is
a water supply flow rate sensor that monitors the flow rate of water in the water supply;
A water supply flow rate sensor for detecting the flow rate in the water supply;
A water pressure measurement sensor that measures the water pressure in the water supply, and
Water and sewage monitoring system, characterized in that it comprises a water quality measurement sensor for measuring the water quality in the water supply
The method of claim 1,
The sewage detection sensor is
a sewage flow rate sensor that monitors the flow rate of sewage flowing inside the sewer;
Sewerage flow rate sensor for detecting the flow rate in the sewer;
Water and sewage monitoring system, characterized in that it comprises a sewage water pressure measuring sensor for measuring the water pressure in the water supply
The method of claim 1,
The water and sewage management server,
Includes a schedule setting module that allows and blocks waterworks according to the schedule setting information stored in the waterworks management server through the manager terminal,
The schedule setting information is
Water and sewage monitoring system, characterized in that control information according to month, date, and time in controlling the water supply
4. The method according to claim 2 or 3,
The manager terminal,
Water and sewage monitoring system, characterized in that it shows the water and sewage information received through the water and sewage management server in a graph
4. The method of claim 2 or 3,
The water and sewage management server,
Including a water and sewage abnormality detection module,
The abnormality detection module compares the flow rate, flow rate, water pressure, and water quality information derived through the detection sensor with the flow rate, flow rate, water pressure, and water quality information previously stored in the database. Water and sewage monitoring system, characterized in that the details are transmitted to the manager terminal
4. The method of claim 2 or 3,
The water and sewage management server,
Includes a water quality monitoring module and a sewage blocking module,
The water quality monitoring module,
In connection with the water quality measurement sensor, when the water pollution level of the water supply exceeds the allowable amount, the details are transmitted to the sewage blocking module,
The sewage blocking module is
Water and sewage monitoring system, characterized in that it blocks the water supply in which the sewage details are detected
The method of claim 1,
The water and sewage monitoring system,
Further comprising a leak detection module,
The leak detection module,
A first measurement sensor provided on the inner wall of the inlet in the direction in which water flows into the water and sewage to monitor the inflow of water and sewage; and
It is provided on the inner wall of the outlet in the direction in which water is discharged to the water supply and sewerage, and includes a second measurement sensor for monitoring the discharge amount of the water and sewage;
Water and sewage monitoring system, characterized in that when abnormal details occur in the information derived from the first measurement sensor and the second measurement sensor, the details are transmitted to a manager terminal
The method of claim 1,
The water and sewage
a flow control diaphragm for controlling the flow rate of water and sewage flowing inside;
A pressure control means for regulating the pressure inside the water and sewage by opening and closing one side of the water and sewer according to the pressure inside the water and sewage; and
Water and sewage monitoring system, characterized in that it includes a guide pipe for guiding the water discharged from the water and sewage when one side of the water and sewage is opened by the pressure control means.

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