KR20200100272A - Monitoring and control system of sewage facilities using multi path communication devices - Google Patents

Abstract

The present invention relates to a water supply and sewage meter control system using a multi-path communication device. According to the present invention, the water supply and sewage meter control system using a multi-path communication device comprises: a water supply and sewage detection unit; a constant monitoring terminal connected to the water supply and sewage detection unit; an emergency monitoring terminal connected to the water supply and sewage detection unit; an emergency capacitor; a first timer; a first latch relay; a multi-path communication device; and a management server. According to the present invention, a major accident due to a rise in the water level can be prevented.

Description

Water and sewage measurement control system using multi-path communication device {MONITORING AND CONTROL SYSTEM OF SEWAGE FACILITIES USING MULTI PATH COMMUNICATION DEVICES}

The present invention relates to a water and sewage measurement control system using a multi-path communication device, and more particularly, a terminal for constant monitoring that collects information detected from a water and sewage detection unit in a normal situation, and collects information detected from the water and sewage detection unit in an emergency. Equipped with an emergency monitoring terminal, the constant monitoring terminal transmits the status information of water and sewage facilities collected in a normal situation to the management server through wired communication, and the emergency monitoring terminal transmits the status information of the water and sewage facilities collected in an emergency by wireless communication. By transmitting to the management server, it is possible to measure and manage the state of water and sewage facilities without interruption even in emergencies such as lightning strikes, and measure and alarm the water level of water and sewage facilities through mechanical water gauges. It relates to a water and sewage measurement and control system using a multi-path communication device that can prevent accidents in advance.

In general, water supply and sewage facilities for managing water supply and sewage used in homes and industrial facilities are water intake stations for intake of raw water, intake wells that control the amount and level of water from the water intake facilities, and water purification chemicals are injected and mixed well. A settling paper that allows chemicals and foreign substances to become agglomerated with each other, a sedimentation paper that sinks condensed matter in water and throws away debris and sends only clear water to the filter paper, a filter paper that filters very small aggregates that could not be removed from the settling pond, and A chlorine input room that removes various germs, a water purification plant that temporarily stores clean water that has passed through a filter paper and a chlorine input room, a drainage reservoir that stores water from the water purification plant and sends it to each household, and when the water from the purification plant is sent to a drainage reservoir (water supply process ) It includes a pressurization station and relay pumping station for pressurized water supply and relay transmission by pumping.

A control system is required for the management of water and sewage facilities.

In general, the control system of a water and sewage treatment plant is installed in more than one place, and a plurality of detection devices are connected to detect physical, chemical or biological factors such as water level, water temperature, pollution level, pressure, flow rate, flow rate, carbon dioxide concentration, and water quality. Has been.

Meanwhile, according to the conventional water and sewage facility monitoring system, the management server monitors whether the remote water supply and sewage facilities are normally operated based on the information received from the monitoring terminal, and the facilities in which abnormalities occur are controlled by a separate remote control system. It enables integrated monitoring and control of water and sewage facilities by taking measures such as dispatching repair staff or other measures.

However, in the conventional water and sewage facility monitoring system, when a communication line is disconnected due to lightning or the like, or an abnormal voltage is induced in the monitoring terminal and the monitoring terminal becomes inoperative, there is a problem that communication between the monitoring terminal and the management server is cut off.

In such a communication interruption situation, the monitoring function of water and sewage facilities is fundamentally blocked, and problems such as not being able to quickly respond to failures in water and sewage facilities have arisen.

In addition, according to the prior art, the use of an electronic sensor causes frequent malfunctions due to rain or lightning, and thus, there is a problem in that a large accident occurs due to flooding of water and sewage in a water tank of a water supply and sewage facility.

Korean Patent Registration No. 10-0449751 Korean Patent Registration No. 10-0771222

The present invention is to solve the above-described problem, by transmitting the water and sewage information detected from the water and sewage detection unit to the management server at all times, as well as transmitting the water and sewage information to the management server using emergency power in case of failure of the constant monitoring equipment. It can measure and manage the state of water and sewage facilities without interruption even in emergencies such as, etc., and also measure and alarm the water level of water and sewage facilities through mechanical water gauges to prevent large-scale accidents caused by water level rise even in case of malfunction of electronic equipment. It is to provide a water and sewage measurement control system using a multi-path communication device.

As a means to achieve the above object,

The present invention is a flow meter for measuring the flow rate in water and sewage facilities, a water level meter for measuring the water level, a leak detection unit for detecting the presence of water leakage, a water quality meter for measuring the state of water quality, and an inflow for detecting whether the inlet valve is opened or closed. A water and sewage detector for detecting a state of water and sewage facilities by installing a valve detector and an outlet valve detector for detecting whether or not the outlet valve is opened or closed; A terminal for constant monitoring connected to the water and sewage detection unit and collecting information on the flow rate, water level, leakage, water quality, inlet valve opening and closing, outlet valve opening and closing, and abnormality of the water supply and sewage facility under normal circumstances; An emergency monitoring terminal connected to the water supply and sewage detection unit and collecting information on the flow rate, water level, leakage, water quality, inlet valve opening/closing, outlet valve opening/closing, and abnormality of water supply and sewage facilities detected from the water supply and sewage detection unit in an emergency; An emergency capacitor for supplying power to the emergency monitoring terminal in case of an emergency; A first timer operated by supplying power to the emergency storage battery when the terminal for constant monitoring is inoperative; A first latch relay for switching and controlling the power of the emergency storage battery to be connected to the emergency monitoring terminal when the time set by the first timer elapses; A multi-path communication device that transmits the state information of water and sewage facilities collected by the constant monitoring terminal through wired communication when normal, and transmits the state information of water and sewage facilities collected by the emergency monitoring terminal through wireless communication; And a management server for managing state information of water and sewage facilities transmitted from the constant monitoring terminal or the emergency monitoring terminal, wherein the multi-path communication device includes the constant monitoring terminal and the management server using a dedicated line. Implement wired communication between, and implement wireless communication between the emergency monitoring terminal and the management server, and the emergency monitoring terminal is a buoyant inlet water level meter 150 for measuring the water level, and controlling the outflow of water stored in the water tank A buoyant outlet water level gauge, a structure that surrounds the buoy while the top and bottom are open, and a dovetail-shaped rail groove (156a) in which the buoy is mounted so as to be slid up and down is provided on the inner circumferential surface, so that both left and right sides are on the rail while surrounding the buoy. Including a fixed protective cover 156, the buoyancy-type inlet water level meter 150 is a rail 151 having a dovetail-shaped rail groove that is installed in a vertical direction in a water tank 1 of a water and sewage facility, a dovetail A float 152 that is mounted to the rail so as to be elevating and descends on the rail through a type of connection part, a float 152 that is installed in the form of a seesaw on the top of the float and rotates by the float, the A motor 154 connected to the valve 3 for opening and closing the inlet pipe connected to the water tank and closing the inlet pipe by driving the valve by a change in contact point of the valve adjustment switch, and a warning sound when the contact point of the valve adjustment switch changes Consisting of an output speaker 155, the buoyancy-type outlet water level meter is a rail installed in the vertical direction on the outlet side of the water tank, a float mounted on the rail so as to be elevating and floating in the water in the water tank, A valve control switch installed at the top and rotated by a buoy, connected to a valve that opens and closes an outlet pipe connected to the water tank, and a motor configured to close the outlet pipe by driving the valve by a contact change of the valve adjustment switch. , The protective cover is equipped with the valve adjustment switch, is electrically connected to the valve adjustment switch, and the water level is above the standard It is characterized by including a odor chemical application device that outputs odor to the outside.

In addition, the odor application device 1100 includes a housing 1110; A battery 1120 installed inside the housing 1110 and receiving power from the outside to charge electricity and then supply electricity to the device; A rotary motor (1130) electrically connected to the battery to receive power from the battery and convert it into a mechanical rotary motion; A motor shaft (1131) installed on the central axis of the rotary motor to rotate in response to the rotation of the rotary motor, but having a bottom surface in a waveform shape and continuously rotating in a curved waveform shape; A vertical drive cylinder (1140) located at the lower end of the rotary motor and flowing while moving up and down by converting the rotation of the rotary motor into a reciprocating vertical motion; It is located above the vertical drive cylinder 1140, but is located on the central axis, and is mechanically contacted while being in contact with the motor shaft 1131 of the rotary motor 1130, and is coupled with the motor shaft 1131 of the rotary motor 1130. And a rotation shaft 1141 for elevating and descending while repeating the separation. Installed on the outer periphery of the vertical driving cylinder 1140, one side is fixed to the locking jaw inside the housing and the other side is fixed to the locking jaw of the vertical driving cylinder to elastically support the vertical driving cylinder to maintain the vertical driving cylinder An elastic spring 1150 for supporting elevating and descending to enable it to be; It is inserted and coupled to the inner side of the up and down drive cylinder 1140, is generally cylindrical and consists of a plurality of drug passage holes 1161 installed on the bottom, and supplies drugs while flowing up and down according to the movement of the up and down drive cylinder. An odor drug applicator 1160; One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the up and down driving cylinder and the odor drug applicator 1160 are temporarily fixed at the same time based on the housing to temporarily fix the odor drug applicator 1160. It is characterized by comprising a odor drug applicator temporary fixing means (1180) to prevent falling down by the action of gravity.

In addition, the odor drug applicator temporary fixing means 1180 is formed in a wedge shape with a sharp end, and is forcibly fitted through the coupling hole of the up and down driving cylinder and the coupling hole of the drug applicator, so that the odor drug applicator is A locking hook 1181 for maintaining a state coupled to the inner circumference; A connecting piece 1182 which is integrally connected to the hook for hook 1181 in a diagonal direction and guides the hook for hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion; A hinge for supporting rotation (1183) installed between the connecting piece (1182) and the hook (1181) for supporting the connecting piece to rotate; It is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the hook for locking 1181 flows counterclockwise to keep the drug applicator connected to the vertical driving cylinder. , When the connecting piece is pressed by an external force and compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the drug applicator 1160, and the drug applicator 1160 is a vertical driving cylinder. A support spring 1184 for guiding it to be removed from the 1140; A sliding flow piece (1185) installed at the end of the connecting piece (1182) and moving at the same time when the hook (1181) and the connecting piece (1182) move up and down according to the vertical flow of the vertical drive cylinder (1140); It is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, the connecting piece 1182 is pushed in the vertical drive cylinder 1140 direction. As the connection piece 1182 is rotated around the hinge pin 1183 for rotation support by pressing, the hook for hook 1181 is separated from the vertical drive cylinder 1140 and the drug applicator 1160, and the odor drug applicator 1160 ) Is characterized in that it comprises a push button (1186) to induce removal from the vertical drive cylinder (1140).

According to the water and sewage measurement control system using a multi-path communication device according to the present invention, it is possible to measure and manage the state of water and sewage facilities without interruption even in an emergency such as a lightning strike, and a water level meter with a mechanical configuration that does not have a failure compared to the electronic method. There is a technical effect of preventing large-scale accidents caused by rising water levels by detecting the water level and maintaining the water tank at a safe level.

1 shows the configuration of a water and sewage measurement control system using a multi-path communication device according to the present invention.
2 shows a circuit configuration for explaining the operation of the emergency monitoring terminal and the constant monitoring terminal when an emergency state occurs according to the present invention.
3 is a block diagram of a buoyancy type inlet water level meter applied to the water and sewage measurement control system using a multi-path communication device according to the present invention.
Figure 4 is a state diagram of the operation of the buoyancy type inlet water level meter applied to the water and sewage measurement control system using a multi-path communication device according to the present invention.
Figure 5 is a view applied to the protective cover to the buoyancy-type inlet water level meter of the water and sewage measurement control system using the multi-path communication device according to the present invention.
6 is a block diagram of a valve adjustment switch and a odor chemical application device according to the present invention.
Figure 7 is an exploded perspective view of the odor chemical application device of the present invention.
Figure 8 is a cross-sectional view and a cross-sectional view of the main portion of the odor chemical application device of the present invention.
Figure 9 is an enlarged cross-sectional view of the main part of the odor chemical application device of the present invention.
Figure 10 is a configuration diagram of a rotary motor and a vertical drive cylinder of the odor chemical application device of the present invention.
11 is an enlarged view of the main parts of the rotating motor and the vertical drive cylinder of the odor chemical application device of the present invention.
12 is a block diagram of a temporary fixing means of the odor chemical application device of the present invention.
Figure 13 is another angular configuration of the temporary fixing means of the odor chemical application device of the present invention.
14 is a configuration diagram of a hole for passing a chemical solution according to the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

In addition, a preferred embodiment of the present invention to be implemented below is already provided in each system function configuration in order to efficiently describe the technical components constituting the present invention, or system functions commonly provided in the technical field to which the present invention belongs. The configuration will be omitted as much as possible, and a functional configuration that should be additionally provided for the present invention will be mainly described.

If one of ordinary skill in the art to which the present invention pertains, among the functional configurations not shown below and omitted, the functions of the components already used in the past will be easily understood, and the configurations omitted as described above. The relationship between the elements and the elements added for the present invention will also be clearly understood.

In addition, in the following embodiments, terms will be appropriately modified and used so that those of ordinary skill in the art can clearly understand the key technical features of the present invention in order to efficiently describe the core technical features of the present invention. It is by no means limited.

As a result, the technical idea of the present invention is determined by the claims, and the following embodiments are one means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. It is only.

1 shows the configuration of a water and sewage measurement control system using a multi-path communication device according to the present invention.

2 shows a circuit configuration for explaining the operation of the emergency monitoring terminal and the constant monitoring terminal when an emergency state occurs according to the present invention.

3 is a block diagram of a buoyancy type inlet water level meter applied to the water and sewage measurement control system using a multi-path communication device according to the present invention.

Figure 4 is a state diagram of the operation of the buoyancy type inlet water level meter applied to the water and sewage measurement control system using a multi-path communication device according to the present invention.

Figure 5 is a view applied to the protective cover to the buoyancy-type inlet water level meter of the water and sewage measurement control system using the multi-path communication device according to the present invention.

6 is a block diagram of a valve adjustment switch and a odor chemical application device according to the present invention.

Figure 7 is an exploded perspective view of the odor chemical application device of the present invention.

Figure 8 is a cross-sectional view and a sectional view of the main portion of the odor chemical application device of the present invention.

Figure 9 is an enlarged cross-sectional view of the main part of the odor chemical application device of the present invention.

Figure 10 is a configuration diagram of a rotary motor and a vertical drive cylinder of the odor chemical application device of the present invention.

11 is an enlarged view of the main parts of the rotating motor and the vertical drive cylinder of the odor chemical application device of the present invention.

12 is a block diagram of a temporary fixing means of the odor chemical application device of the present invention.

Figure 13 is another angular configuration of the temporary fixing means of the odor chemical application device of the present invention.

14 is a configuration diagram of a hole for passing a chemical solution of the present invention,

First, referring to FIG. 1, a water and sewage measurement and control system 100 using a multi-path communication device according to the present invention includes a water and sewage detection unit 110, a monitoring terminal 120, a multi-path communication device 130, and It is configured to include the management server 140.

The water supply and sewage detection unit 110 installs various sensors in each water supply and sewage facility to detect the state of the water supply and sewage facilities, such as a flow meter 111 for measuring the flow rate, a water level meter 112 for measuring the water level, and whether or not there is a leak. A water leak detection unit 113 to detect, a water quality meter 114 to measure the state of the water quality, an inlet valve detection unit 115 to detect whether the inlet valve is opened or closed, an outlet valve to detect whether the outlet valve is opened or closed It is configured to include the detection unit 116, but is not limited thereto.

The monitoring terminal unit 120 is configured to include a constant monitoring terminal 120a and an emergency monitoring terminal 120b.

The constant monitoring terminal (120a) is connected to the water and sewage detection unit (110), after receiving the information detected from the water and sewage detection unit (110) in a normal situation, this is sent to the management server (140) through the multi-path communication device (130). send.

The emergency monitoring terminal 120b is connected to the water supply and sewage detection unit 110, and in the event of an abnormal situation (for example, a failure of the water supply and sewage measurement control system due to lightning), after receiving the detected information from the water supply and sewage detection unit 110, This is transmitted to the management server 140 through the multi-path communication device 130.

Meanwhile, operations of the emergency monitoring terminal 120b and the like in an abnormal situation will be described later in FIG. 2.

The multi-path communication device 130 includes a wired communication module (not shown) for performing wired communication and a wireless communication module (not shown) for performing wireless communication, and an Internet module (not shown) for performing Internet as needed. (Not shown) may be further included.

In this case, the wired communication module (not shown) communicates in the RS-232 or RS-422 method between the remote control device and the dedicated line modem using a dedicated line provided by a communication company (for example, a dedicated line provided by Korea Telecom). And, preferably, it is used when transmitting and receiving data from the constant monitoring terminal 120a to the management server 140 for stable data transmission and reception.

The wireless communication module (not shown) can implement wireless communication using at least one of Zigbee, RF, WiFi, 3G, 4G, LTE, LTE-A, and Wireless Broadband Internet. It can be, and is preferably used when transmitting and receiving data from the emergency monitoring terminal (120b) to the management server 140 in case of an emergency.

The management server 140 receives various detection signals detected from the water and sewage detection unit 110, analyzes them, and transmits the analyzed information to an external water and sewage facility manager through wired, wireless, and Internet communication, thereby measuring the state of water and sewage facilities. , It enables repair control, etc. in case of abnormality.

2 shows a circuit configuration for explaining the operation of the emergency monitoring terminal and the constant monitoring terminal when an emergency state occurs according to the present invention.

Referring to FIG. 2, the circuit configuration of the monitoring terminal unit 120 is a power supply unit 10, an emergency capacitor 20, a constant monitoring terminal 120a, a first switching unit S10, and a second switching unit. (S20), an emergency circuit unit 30, and an emergency monitoring terminal 120b.

The power supply unit 10 supplies constant power to the constant monitoring terminal 120a or the emergency capacitor 20.

The emergency capacitor 20 is used as a dedicated power source for the operation of the emergency monitoring terminal 120b, and the constant monitoring terminal 120a is normally operated, and a wired between the constant monitoring terminal 120a and the management server 140 While the communication network is operating normally, power supplied from the power supply unit 10 is stored.

The first switching unit S10 is located in two lines between the power supply unit 10 and the emergency capacitor 20, and is in a switched-on state in a normal situation, and in an emergency situation, for example, an abnormal voltage due to lightning strikes. The switch is turned off to block the emergency capacitor 20 from being caught.

Likewise, the second switching unit S20 is located in two lines between the power supply unit 10 and the constant monitoring terminal 120a, and is in a switched-on state in a normal situation, and in an emergency situation, for example, It is switched off so as to block the abnormal voltage caused by lightning from being applied to the constant monitoring terminal 120a.

The emergency monitoring terminal (120b) is operated by receiving power from the emergency storage battery (20), and information such as whether the valve is opened or closed, flow rate, hydraulic pressure, water level in each reservoir, leakage, etc. collected from water and sewage facilities through a wireless communication network The presence or absence of the facility is transmitted to the management server 140.

In this case, the emergency monitoring terminal (120b) is preferably to perform limited monitoring compared to the constant monitoring terminal (120a), which is because the emergency monitoring terminal (120b) is operated by a separate emergency storage battery (20). , It is to prevent network traffic by minimizing power consumption and minimizing data transmitted and received wirelessly.

Hereinafter, the operation of the emergency monitoring terminal 120b when an emergency situation such as lightning occurs will be described.

At both ends of the power line of the emergency storage battery 20, when the constant monitoring terminal 120a is inoperable, the first timers T1 and 30 operated by supplying the power of the emergency storage battery 20, and a first timer When the time set by (T1, 30) elapses, the first latch relay (LR1, 50), which is set and connects the power of the emergency storage battery 20 to the emergency monitoring terminal 120b, and the first latch relay Second timer (T2, 40) that operates when the constant monitoring terminal (120a) returns to normal when (LR1, 50) is set and resets (RST) the second latch relays (LR2, 60) after the set time Are each connected in parallel.

In more detail, the first timer (T1, 30) includes a relay b contact (S31) that opens and closes according to the operation of the constant monitoring terminal (120a) or the normal operation of the wired communication network, and the second latch relay (LR2, 60). ) Of contact b (S32) is connected in series. That is, under the assumption that the second latch relays LR2 and 60 are in a reset state, the first timers T1 and 30 start to operate when the constant monitoring terminal 120a falls into an inoperative state.

In this case, it is preferable to set the setting time in the range of about 20 seconds to 30 seconds for the first timers T1 and 30.

As described above, the first timers T1 and 30 are used to add a predetermined delay time to the operation of the emergency monitoring terminal 120b in order to block the abnormal voltage from flowing into the emergency monitoring terminal 120b when a lightning strike occurs. It also serves to prevent the emergency monitoring terminal (120b) from operating for negligible failures such as momentary power failure.

In addition, by connecting the b contact (S32) of the second latch relay (LR2, 60) to the power supply line of the first timer (T1, 30) in series, the first timer only when the emergency monitoring terminal (120b) is initially operated. Power is supplied to (T1, 30), and after the second latch relay (LR2, 60) is operated, the power supply of the emergency storage battery 20 to the first timers (T1, 30) is cut off. (20) cut off unnecessary power consumption.

The first latch relay (LR1, 50) and the second latch relay (LR2, 60) are each separately provided with a set (SET) coil and a reset (RST) coil, and are set when current is applied to the set coil, and then The set state is maintained even when the power is cut off, and it is reset only when a current is applied to the reset coil. This is to minimize the power consumption of the emergency storage battery 20 compared to a general relay in which current is continuously applied. .

A contact point S50 of the first timers T1 and 30 is connected in series to the set coils of the first latch relays LR1 and 50.

That is, after the first timers T1 and 30 are operated and the set time has elapsed, the first latch relays LR1 and 50 are set. When the first latch relays LR1 and 50 are set, the contact a (S70, S80) of each of the latch relays installed in the power line 2 of the emergency monitoring terminal 120b is turned on, and the emergency monitoring terminal Power to the emergency storage battery 20 is supplied to 120b.

Accordingly, the emergency monitoring terminal 120b starts operation and transmits the main monitoring data collected from the water supply and sewage facilities to the management server 140 through a wireless communication network.

In the second timer (T2, 40), the relay a contact (S41), which is contacted when the constant monitoring terminal (120a) returns to normal operation, and the a contact (S42) of the first latch relays (LR1, 50), are in series. Connected. Accordingly, the second timers T2 and 40 start to operate when the constant monitoring terminal 120a returns to normal while the first latch relays LR1 and 50 are set.

A contact point S60 of the second timers T2 and 40 is connected in series to the reset coil of the second latch relays LR2 and 60. That is, as described above, when the second timers T2 and 40 start to operate and the set time of the second timers T2 and 40 elapses, the second latch relays LR2 and 60 are reset.

Therefore, the a contact point (S70, S80) of each of the latch relay installed in the power line 2 of the emergency monitoring terminal (120b) is turned off (turn off), the emergency monitoring terminal (120b) stops operation.

Figure 3 shows a buoyancy type inlet water level meter 150 applied to the emergency monitoring terminal applied to the present invention. The emergency monitoring terminal has an effect of blocking the rise of the water level when the electronic equipment malfunctions by including a buoyancy type inlet water level meter 150 having a mechanical configuration while sharing a water level meter by electronic sensing together with a constant monitoring terminal.

The buoyant inlet water level gauge 150 is connected to the rail 151 through a dovetail-shaped rail groove 151a, which is installed in the water tank 1 of the water and sewage facility in the vertical direction. A float 152 that is mounted to be elevating and floats in the water (water, sewage) filled in the water tank 1, a valve adjustment switch 153 that is installed on the upper part of the float 152 and rotates by the float 152, a water tank A motor 154 that is connected to the valve 3 that opens and closes the inlet pipe 2 connected to (1), and drives the valve 3 by a change in contact point of the valve adjustment switch 153 to close the inlet pipe 2 , And a speaker 154 that outputs a warning sound when the contact point of the valve adjustment switch 153 changes.

The bugu 152 has a tubular structure in which air is filled therein, and only elevates and descends from the rail groove of the rail 151 through the dovetail connection.

The valve adjustment switch 153 is mounted in the form of a seesaw through a hinge at a central portion, and a terminal on one side is disposed on the accessory 152 and a terminal on the other side is disposed at a place for an ON contact of the motor 154. The valve adjustment switch 153 may be installed through a spring or the like so that the motor 154 maintains the OFF contact at normal times.

The motor 154 receives power from the emergency capacitor 20 and turns on the valve 3 by receiving power when it is in contact with the valve adjustment switch 153. The valve 3 is a butterfly valve and is rotatably mounted inside the inlet pipe 2 to adjust the opening degree of the inlet pipe 2.

The water level at which the motor 154 is turned on is the highest level, which is the level at which water can overflow in the tank 1.

The motor 154 may be directly connected through a shaft for rotation of the valve 3 or indirectly connected through a gear or the like.

The speaker 155 receives power from the emergency capacitor 20 and outputs an alarm sound when the valve adjustment switch 153 or the motor 154 is on contact to inform the manager that the water level has reached the highest level.

In addition, as described above, the contact change of the valve adjustment switch 153 or the motor 154 or the change in opening/closing of the inlet pipe 2 is transmitted to the management server through wireless communication, so that even remote managers can quickly know the rise in water level. .

3 is a case where the water level of the water tank 1 is below the maximum water level, and the bugu 152 rises or falls according to the water level of the water tank 1, and the motor 154 maintains the OFF contact because the water level is lower than the maximum water level. do.

On the other hand, when the water level rises and reaches the maximum water level, as shown in FIG. 4, the valve adjustment switch 153 is rotated by the buoy 152 and the motor 154 is turned on.

Accordingly, the power of the emergency capacitor 20 is applied to the motor 154, the motor 154 is driven, the valve 3 rotates, and the inlet pipe 2 is closed.

Therefore, no more water flows into the tank 1 and water flows out through the outlet pipe 4, so that the inside of the tank 1 is maintained at a safe level.

As described above, the buoyancy-type inlet water level meter 150 has the effect of maintaining the water level in the water tank 1 as a safe water level in case of malfunction of the electronic equipment by blocking the inflow of water by raising and lowering the buoy 152 based on the water level. .

Meanwhile, the buoyant outlet water level gauge may be configured in the same manner as the buoyancy inlet water level 150 so that a certain amount of water is stored in the water tank 1.

The buoyant outlet water level meter is composed of a rail, a buoy, a valve adjustment switch, and a motor that drives the valve of the outlet pipe, like the buoyant inlet water level meter 150, whereby water is transferred to the water tank 1 through the outlet pipe. It can prevent backflow.

In addition, a protective cover 156 may be applied for normal operation and protection of the accessory 152.

The protective cover 156 has a structure that is open toward the upper and lower portions and the rail 151, and both sides are fixed to the rail 152 while covering the bracket 152.

The protective cover 156 has a dovetail-shaped rail groove 156a formed in the vertical direction in the vertical direction so that the accessory 152 moves up and down without twisting. The protective cover 156 does not touch the bottom of the water tank 1 so that water flows from the bottom. In addition, a locking jaw is formed at the bottom portion to support the attachment portion 152 so that the attachment portion 152 does not fall into the bottom portion.

Therefore, the bugu 152 is not affected by the flow of water and sewage from the inside of the protective cover 156 and stably rises and descends by the water level, so that damage is prevented and accurate operation is possible.

The protective cover 156 protects the bracket 152 and provides a space for the valve adjustment switch 153 or the valve adjustment switch 153 and the motor 154 to be installed. You can also simplify the task.

On the other hand, the water quality meter 114 is mounted on the bugu 152 and is installed so as to rise and fall by the bugu 152, and therefore, it is possible to secure the reliability of the data by always detecting the water quality of a certain depth (a certain depth from the water surface). have.

On the other hand, the present invention is provided with a odor chemical liquid coating device 1100 in addition to a speaker as an alarm signal output means, if the water level is above the standard, the odor is output from the odor chemical liquid application device 1100 to induce the operator to take action. do.

That is, when the valve adjustment switch 153 is contacted, it further includes a odor chemical application device that applies odor to the outside by contacting the valve control switch 153, and informs that the water level is in a dangerous state above the standard through the odor along with the speaker.

The odor chemical application device 1100 includes a housing 1110, a battery 1120, a rotary motor 1130, an up and down drive cylinder 1140, an elastic spring 1150 for lifting and lowering support, and an odor drug applicator. It consists of (1160), a chemical liquid storage means (1170), and an applicator temporary fixing means (1180).

The housing 1110 has a space therein, and is formed by embedding various devices. That is, the housing is configured by bonding two cases with one side open to each other, and various devices are installed in a space portion generated in the process of bonding the cases. Such a housing is generally of a structure similar to the means having a space therein.

The battery 1120 is installed inside the housing 1110 and serves to supply electricity to the device after charging electricity by receiving power from the outside. That is, the battery is installed on the upper part of the housing and is electrically connected to an external power supply to receive electricity, and temporarily stores the supplied power to supply electricity to various devices that require power.

The rotary motor 1130 is electrically connected to a battery and receives power from the battery and converts it into a mechanical rotational motion to freely rotate the motor shaft. At this time, the motor shaft 1131 has a shape in which a bottom surface is formed in a waveform shape in a vertical direction so that a curved waveform shape continuously rotates. That is, the rotary motor rotates by receiving power from a battery, and the bottom surface of the motor shaft is formed in a curved waveform to rotate.

The vertical drive cylinder 1140 is mechanically connected to the rotary motor, but is moved while moving up and down by converting the rotation of the rotary motor into a reciprocating vertical motion. At this time, the rotation shaft 1141 of the vertical drive cylinder 1140 has an upper surface in a shape of a waveform in a vertical direction, and moves up and down while repeating mutual coupling and separation with the waveform of the motor shaft of the rotary motor. In other words, the vertical driving cylinder is formed in the form of a curved waveform in the same way as the motor shaft of the rotating motor so that the vertical movement is performed according to the rotation of the rotating motor, and accordingly, when the rotating motor rotates, the vertical driving cylinder moves up and down. Will do.

The lifting and lowering support elastic spring 1150 is installed on the outer periphery of the vertical driving cylinder 1140, but one side is fixed to the locking jaw inside the housing 1110 and the other side is fixed to the locking jaw of the vertical driving cylinder 1140 The vertical driving cylinder 1140 is elastically supported so that the vertical driving cylinder 1140 can maintain the lifting operation. That is, since the elastic spring 1150 for elevating and descending supports the elasticity of continuously pushing the vertical drive cylinder 1140 upward, the waveform of the motor shaft 1131 of the rotary motor and the The vertical drive cylinder descends as the waveforms of the rotation shaft 1141 of the vertical drive cylinder 1140 are staggered, and after the staggering is over, the vertical drive cylinder 1140 rises by the elastic spring 1150 for lifting and lowering support. The waveform of 1141 and the waveform of the motor shaft 1131 of the rotary motor 1130 are in close contact. Accordingly, the vertical driving cylinder 1140 is repeatedly close to and spaced apart from the rotary motor 1130, so that the vertical driving cylinder 1140 continuously moves vertically around the rotary motor 1130.

The odor drug applicator 1160 has a body cylinder shape and has a plurality of odor drug passage holes 1161 installed on the bottom surface, is inserted and coupled to the inside of the up and down drive cylinder 1140, and supplies odor drugs. Plays a role. That is, the odor drug applicator 1160 allows the odor drug stored therein to be discharged to the outside through the odor drug passage hole 1161, and at this time, the odor drug applicator 1160 is installed inside the vertical driving cylinder. Therefore, when the vertical driving cylinder 1140 is operated up and down, the odor drug applicator 1160 is hit, and the drug is output to the outside according to the law of inertia.

The odor drug storage means 1170 is in a state in which the odor drug is accommodated, and is inserted and installed in the odor drug applicator 1160 to be output through the odor drug passage hole 1161 of the odor drug applicator 1160. . That is, the malodor chemical liquid storage means 1170 is in a state in which the drug is stored, and the lower part is coupled to the malodor drug applicator 1160 in an open form, and when the vertical drive cylinder 1140 is driven, the malodor of the malodor chemical liquid storage means The drug is output to the outside. In fact, since the odor drug passage hole 1161 is formed finely, it is not easily discharged to the outside when the vertical drive cylinder 1140 is not operated.

The odor drug applicator temporary fixing means 1180 has one side coupled to the odor drug applicator 1160 and the other side coupled to one end of the housing 1110, and a vertical driving cylinder 1140 based on the housing 1110 and By temporarily fixing the odor drug applicator 1160 at the same time, the up and down driving cylinder 1140 and the odor drug applicator 1160 flow up and down while preventing the odor drug applicator 1160 from falling down due to gravity When replacing the odor drug applicator 1160, the odor drug applicator is released from the vertical drive cylinder by pressing the button to release the fixation of the odor drug applicator based on the housing so that the odor drug applicator is separated from the vertical driving cylinder and removed downward. That is, the odor drug applicator temporary fixing means prevents the odor drug applicator from being removed during operation by temporarily fixing the up and down driving cylinders and the odor drug applicator, and after using all the drugs existing inside the odor drug applicator, the button After releasing the odor drug applicator by pressing, the odor drug storage means is induced to be re-stored.

The temporary fixing means 1180 includes a hook for locking 1181, a connecting piece 1182, a hinge for rotation support 1183, a spring for support 1184, a sliding piece 1185, and a push button 1186).

The hook for hook 1181 is formed in a wedge shape with a sharp end and is forcibly fitted through the coupling hole 1140a of the vertical drive cylinder 1140 and the coupling hole 1160a of the drug applicator 1160 to apply odor drugs. The machine 1160 maintains a state coupled to the inner periphery of the vertical drive cylinder 1140.

The connecting piece 1182 is integrally connected to the locking hook 1181 in a diagonal direction, and induces the locking hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion.

The rotation support hinge 1183 is installed between the connecting piece 1182 and the hook 1181 for locking, and serves as a central axis through which the connecting piece is rotated.

The support spring 1184 is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the locking hook 1181 flows in a counterclockwise direction, so that the drug applicator is coupled to the vertical driving cylinder. It functions to maintain the state, and when the connecting piece is pressed by an external force and is compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the odor drug applicator 1160, Induces the applicator 1160 to be removed from the vertical drive cylinder 1140.

The sliding flow piece 1185 is installed at the end of the connecting piece 1182 and moves simultaneously when the hook for locking 1181 and the connecting piece 1182 move up and down according to the up and down flow of the up and down driving cylinder 1140.

The push button 1186 is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, it moves in the vertical direction cylinder 1140 By pushing and pressing the connecting piece 1182, the connecting piece 1182 rotates around the hinge pin 1183 for rotation support, so that the hook for locking 1181 is moved up and down from the cylinder 1140 and the odor drug applicator 1160. As it is separated, it serves to induce the odor drug applicator 1160 to be removed from the vertical driving cylinder 1140.

110: water and sewage detection unit
111: flow meter, 112: water level meter, 113: leak detection unit
114: water quality meter,
115: inlet valve detection unit, 116: outflow valve detection unit,
120: monitoring terminal,
120a: constant monitoring terminal,
120b: emergency monitoring terminal,
130: multi-path communication device,
140: management server,
150: buoyancy type inlet water level meter,
151: rail, 152: bugu
153: valve adjustment switch, 154: motor
155: speaker, 156: protective cover

Claims (3)

A flow meter to measure the flow rate in water and sewage facilities, a water level meter to measure the water level, a leak detection unit to detect whether or not water leakage, a water quality meter to measure the state of water quality, an inlet valve detection unit to detect whether the inlet valve is opened or closed, and A water and sewage detector for detecting a state of a water and sewage facility by installing an outlet valve detector for detecting whether or not the outlet valve is opened or closed;
A terminal for constant monitoring connected to the water and sewage detection unit and collecting information on the flow rate, water level, leakage, water quality, inlet valve opening and closing, outlet valve opening and closing, and abnormality of the water supply and sewage facility under normal circumstances;
An emergency monitoring terminal connected to the water supply and sewage detection unit and collecting information on the flow rate, water level, leakage, water quality, inlet valve opening/closing, outlet valve opening/closing, and abnormality of water supply and sewage facilities detected from the water supply and sewage detection unit in an emergency;
An emergency capacitor for supplying power to the emergency monitoring terminal in case of an emergency;
A first timer operated by supplying power to the emergency storage battery when the terminal for constant monitoring is inoperative;
A first latch relay for switching and controlling the power of the emergency storage battery to be connected to the emergency monitoring terminal when the time set by the first timer elapses;
A multi-path communication device that transmits the state information of water and sewage facilities collected by the constant monitoring terminal through wired communication when normal, and transmits the state information of water and sewage facilities collected by the emergency monitoring terminal through wireless communication; And
And a management server for managing status information of water and sewage facilities transmitted from the constant monitoring terminal or the emergency monitoring terminal,
The multipath communication device,
Implement wired communication between the constant monitoring terminal and the management server using a dedicated line,
Implement wireless communication between the emergency monitoring terminal and the management server,
The emergency monitoring terminal has a buoyant inlet water level meter 150 for measuring the water level, a buoyant outlet water level meter for controlling the outflow of water stored in the water tank, and a structure that surrounds the float while the upper and lower portions are open, and the float slides up and down on the inner circumferential surface. A dovetail-shaped rail groove (156a) is provided so as to be mounted, and includes a protective cover 156 fixed to the left and right sides while surrounding the buoy,
The buoyancy-type inlet water level meter 150 is a rail 151 having a dovetail-shaped rail groove installed in the water tank 1 of a water supply and sewage system in a vertical direction, and a dovetail-type connection part to allow ascending and descending to the rail. A float 152 that is mounted and floats in the water filled in the water tank, a valve adjustment switch 153 installed in the form of a seesaw on the upper part of the float and rotates by the float, and a valve for opening and closing the inlet pipe connected to the water tank (3 ) Is connected to the motor 154 to close the inlet pipe by driving the valve by a change in contact point of the valve control switch, and a speaker 155 that outputs a warning sound when the contact point of the valve control switch changes,
The buoyant outlet water level gauge is a rail installed in the vertical direction on the outlet side of the water tank, a float mounted on the rail so as to be elevating and floating in the water in the tank, and a valve installed on the top of the float and rotated by the float It is connected to a control switch, a valve that opens and closes the outlet pipe connected to the water tank, and comprises a motor that closes the outlet pipe by driving the valve by a contact change of the valve adjustment switch,
The protective cover is equipped with the valve adjustment switch,
Water and sewage measurement and control system using a multi-path communication device, characterized in that it comprises a device that is electrically connected to the valve adjustment switch and outputs an odor to the outside when the water level is above a standard. The method of claim 1,
The odor application device 1100,
A housing 1110;
A battery 1120 installed inside the housing 1110 and receiving power from the outside to charge electricity and then supply electricity to the device;
A rotary motor (1130) electrically connected to the battery to receive power from the battery and convert it into a mechanical rotary motion;
A motor shaft (1131) installed on the central axis of the rotary motor to rotate in response to the rotation of the rotary motor, but having a bottom surface in a waveform shape and continuously rotating in a curved waveform shape;
A vertical driving cylinder 1140 located at the lower end of the rotating motor and flowing while moving up and down by converting the rotation of the rotating motor into a reciprocating vertical motion;
It is located above the vertical drive cylinder 1140, but is located on the central axis, and is mechanically contacted while being in contact with the motor shaft 1131 of the rotary motor 1130, and is coupled with the motor shaft 1131 of the rotary motor 1130. And a rotation shaft 1141 for elevating and descending while repeating the separation.
Installed on the outer periphery of the vertical driving cylinder 1140, one side is fixed to the locking jaw inside the housing and the other side is fixed to the locking jaw of the vertical driving cylinder to elastically support the vertical driving cylinder to maintain the vertical driving cylinder An elastic spring 1150 for supporting elevating and descending to enable it to be;
It is inserted and coupled to the inner side of the up and down drive cylinder 1140, is generally cylindrical and consists of a plurality of drug passage holes 1161 installed on the bottom, and supplies drugs while flowing up and down according to the movement of the up and down drive cylinder. An odor drug applicator 1160;
One side is coupled to the odor drug applicator 1160 and the other side is coupled to one end of the housing 1110, and the up and down driving cylinder and the odor drug applicator 1160 are temporarily fixed at the same time based on the housing to temporarily fix the odor drug applicator 1160. ) Water and sewage measurement control system using a multi-path communication device, characterized in that the configuration comprises a odor drug applicator temporary fixing means (1180) that prevents from falling down by gravity action. The method of claim 2,
The odor drug applicator temporary fixing means 1180,
A hook for locking (1181) that has a sharp wedge-shaped end and is forcibly fitted through the coupling hole of the vertical drive cylinder and the coupling hole of the drug applicator to keep the odor drug applicator connected to the inner periphery of the vertical drive cylinder. Wow;
A connecting piece 1182 which is integrally connected to the hook for hook 1181 in a diagonal direction and guides the hook for hook 1181 to move in a clockwise or counterclockwise direction by a rotational motion;
A hinge for supporting rotation (1183) installed between the connecting piece (1182) and the hook (1181) for supporting the connecting piece to rotate;
It is installed between the connecting piece 1182 and the vertical driving cylinder 1140 to push the connecting piece outward so that the hook for locking 1181 flows counterclockwise to keep the drug applicator connected to the vertical driving cylinder. , When the connecting piece is pressed by an external force and compressed in the vertical driving cylinder direction, the hook for locking 1181 is separated from the vertical driving cylinder 1140 and the drug applicator 1160, and the drug applicator 1160 is a vertical driving cylinder. A support spring 1184 for guiding it to be removed from the 1140;
A sliding flow piece (1185) installed at the end of the connecting piece (1182) and moving at the same time when the hook (1181) and the connecting piece (1182) move up and down according to the vertical flow of the vertical drive cylinder (1140);
It is slidably coupled with the sliding fluid piece 1185 to support the vertical movement of the sliding fluid piece 1185, and when the odor drug applicator 1160 is replaced, the connecting piece 1182 is pushed in the vertical drive cylinder 1140 direction. As the connection piece 1182 is rotated around the hinge pin 1183 for rotation support by pressing, the hook for hook 1181 is separated from the vertical drive cylinder 1140 and the drug applicator 1160, and the odor drug applicator 1160 ) Is a water and sewage measurement control system using a multi-path communication device, characterized in that it comprises a push button (1186) to induce removal from the vertical drive cylinder (1140).

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