KR102227700B1 - Monitoring and control system of sewage facilities using multi path communication devices - Google Patents

Abstract

The present invention provides a measuring and controlling system of water and sewage using a multi path communication device, which transmits water and sewage information detected from a water and sewage detection unit to an ordinary management server, and transmits the water and sewage information to a management server using emergency power in the case of a failure of an ordinary monitoring device to measure and manage the state of water and sewage facilities without interruption even in an emergency such as lightning, and to measure and make an alarm for the water level of the water and sewage facilities through a mechanical water level gauge, thereby preventing major accidents due to a water level rise even in the event of malfunction of electronic equipment.

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 to be injected and mixed well. A settling paper that allows chemicals and foreign substances to become agglomerated with each other, a sedimentation paper that sinks condensates in water and throws away debris and sends only clear water to the filter paper, and a filter paper that filters very small aggregates that could not be removed from the settling pond. The chlorine input room that removes various germs, the water purification plant that temporarily stores the clean water that has passed through the filter paper and the 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 water purification plant is sent to a drainage reservoir ) 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 a lightning strike or an abnormal voltage is induced in the monitoring terminal and the monitoring terminal becomes inoperative, there is a problem in that communication between the monitoring terminal and the management server is cut off.

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

In addition, according to the prior art, as a sensor according to an electronic method is used, frequent malfunctions are caused 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 problems, 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 by transmitting the water and sewage information to the management server using emergency power in case of a 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 or not the inlet valve is opened or closed. A water and sewage detector for detecting a state of a water and sewage facility by installing a valve detector and an outlet valve detector for detecting whether or not the outlet valve is opened or closed; It is connected to the water supply and sewage detection unit, and under normal circumstances, the flow rate detected from the water supply and sewage detection unit, water level, leakage, water quality, inlet valve open or closed, outlet valve open or closed, and a constant monitoring terminal for collecting information on abnormalities in water supply and sewage facilities. ; An emergency monitoring terminal connected to the water supply and sewerage 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 that is operated by turning on the power of the emergency storage battery when the constant monitoring terminal is inoperable; 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; A management server for managing status information of water and sewage facilities transmitted from the constant monitoring terminal or the emergency monitoring terminal; A main door installed at the entrance door of the server and closed or opened by separating the inside and the outside of the device; An auxiliary door installed to be spaced apart from the main door by a predetermined distance, manufactured in the shape of a square panel corresponding to the shape of the main door, and installed horizontally on the main door to separate the inside and the outside of the device; It is characterized in that it comprises a door frame that fixes one side of the main door and the auxiliary door and the other side is in a forced fitting or open state.

In addition, the main door 1100 includes a door handle 1110 installed at one edge of the thermo-hygrostat, but installed at a height of the human body and spaced a predetermined distance from the edge of the door; A door handle cover (1120) formed in a rectangular panel shape that covers the top, bottom, left, and right of the door handle and has a longer horizontal direction than a vertical direction; A cover closing member (1130) for protecting the door handle cover as a member surrounding the upper and lower portions of the door handle cover; It is installed on one side of the door handle cover and consists of a rotary-type handle and a shaft for coupling, but the shaft for coupling the door handle cover is inserted and coupled, and rotates clockwise or counterclockwise to separate the main door and the auxiliary door. A locking lever 1140 for determining to be in a locked state or an unlocked state; A power transmission wire (1150) connected to one side of the locking lever and rotating in correspondence with the rotation of the locking lever in a clockwise or counterclockwise direction to transmit the power of the locking lever to the outside; It is made by being coupled to the power transmission wire, but at the same time, it is vertically sliding to the door handle cover, and when the power transmission wire is moved by moving the locking lever, it is linked to the auxiliary door or disconnected while moving up and down in connection with it. It is characterized in that it comprises a fixed bolt (1160).

In addition, the auxiliary door 1200 is installed at a predetermined distance apart from the main door, but is installed at a point where the door handle and the door handle cover of the main door are located, and a C-shaped channel is installed inside each door. A guide rail 1210 for coupling or releasing the handle and the door handle cover to induce the main door and the auxiliary door to remain in the engaged or released state; When only the auxiliary door is used separately by being inserted or released into the guide rail, it flows along the guide rail to close the space between the guide rail, and when the main door and the auxiliary door are opened and closed at the same time, the space between the guide rail is A sliding panel 1220 for inducing an open state of the space portion to be naturally maintained by opening the door handle; A panel finishing member 1230 for protecting the sliding panel as a member surrounding the upper and lower portions of the sliding panel; It is installed on the upper and lower portions of the sliding panel, and assists the sliding panel to move forward and backward naturally along the guide rail, and comprises a sliding protrusion 1240 for reciprocating the guide rail in a C-shaped channel left and right.

In addition, the server damage detection means (1) is installed on the body surface of the server for detecting damage to the server; It is installed as a closed line connecting both contacts of the server damage detection means (1), and when the server is damaged, the closed line is disconnected, and accordingly, the damage to the server body is checked and an alarm signal is output to the outside. A conductor (2) for inducing repair of a fault by doing so; An alarm generating means (3) for generating an alarm signal by receiving a predetermined power when the server damage detection means detects damage to the server; It is characterized in that it further comprises the current driving control unit 4 which is switched by receiving a predetermined power voltage and supplies a predetermined power voltage to the alarm generating means as it detects the crack of the conductor.

In addition, the current drive control unit (4) is a first electronic contact means (5) for switching by receiving a predetermined power supply voltage and forming a current path as the server damage detection means is short-circuited; It is characterized by consisting of a second electronic contact means (6) for switching by receiving a predetermined current as the first switch means conducts and forming a current path to the alarm generating means.

In addition, the contaminated air burner unit is further installed at one end of the server, and the contaminated air burner unit includes: a switching means (2221) for supplying spark discharge electricity; A spark discharge re-ignition switching means (2222) for automatically re-igniting the spark discharge by being mounted on the spark discharge electricity supply switching means (2221); A spark discharge re-ignition circuit unit 2223 connected to the spark discharge re-ignition switching means 2222 and outputting a signal for re-ignitioning the spark discharge is installed; The spark discharge re-ignition switch means (2222) is installed on the edge of the spark discharge electricity supply switching means (2221), the pinion gear (2222a) rotating at the same time when the spark discharge electricity supply switching means (2221) rotates Wow; A first sliding transfer member (2222b) formed by forming a rack gear (2222e) on a contact surface with the pinion gear (2222a) and having a cylindrical or square column shape so as to slide horizontally by the rotation of the pinion gear (2222a); A second sliding transfer member (2222c) that is coupled to the inner side of the first sliding transfer member (2222b) and moves in conjunction with the first sliding transfer member (2222b) to switch the spark discharge re-ignition circuit unit (2223); A tension spring 2222d, which is connected to the end of the first sliding transfer member 2222b and the start of the second sliding transfer member 2222b, and serves to maintain the switching state of the spark discharge re-ignition circuit part 2223. Including; The spark discharge re-ignition circuit unit 2223 includes a DC power supply unit 2101 installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries, or general batteries in series; A spark discharge re-ignition switch (2102) which has one end connected to the DC power supply and is switched on when the spark discharge re-ignition switching means is rotated; An oscillation booster circuit part 2103 for outputting a boosted AC current by supplying electricity when the spark discharge re-ignition switch is turned on; A switching unit 2108 for supplying electricity to a discharge electrode connected to the output terminal of the oscillation booster circuit unit and turned on by electric supply; A high-voltage boosting circuit part 2107 installed at an output terminal of the switching part for supplying electricity to the discharge electrode and generating a high voltage; A high-pressure discharge spacer (2113a, 2113b) formed by connecting a high-voltage power supply supplied by the high-voltage boosting circuit unit; A discharge electrode (2114) for inducing a flame to burn by igniting the discharge while being discharged using the power provided by the high-pressure discharge spacer; The discharge electrode and the base end are connected, and the emitter end and the collector end are connected to the oscillation transformer and the switching unit for ignition of the discharge electrode. The power to the negative electrode is cut off to prevent the discharge electrode from being ignited, and when the spark discharge flame is turned off by external wind or moisture, the closed circuit is broken due to the extinction of the hot electrons and the switching is turned off. It is characterized by including a switching unit 2118 for blocking the discharge electrode that functions to induce the discharge electrode to be ignited by turning it on.

According to the water and sewage measurement and 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 lightning, and a water level meter with a mechanical configuration that does not have any troubles compared to the electronic method. There is a technical effect of preventing large-scale accidents caused by a rise in the water level 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 a 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 a multi-path communication device according to the present invention.
Figure 6 is an exemplary server applied to the present invention.
7 is a state diagram of a server auxiliary door closed and a main door opened according to the present invention.
Figure 8 is a conceptual diagram of the operation of the server main door and the locking lever of the present invention.
9 is a conceptual diagram of the operation of the server auxiliary door and the sliding panel of the present invention.
10 is a diagram showing a relationship between the main door and the auxiliary door when the server main door of the present invention is opened by 90 degrees.
11 is a diagram showing the relationship between the main door and the auxiliary door when the server main door of the present invention is opened by 180 degrees.
12 is a flowchart illustrating an operation of filling the space of the auxiliary door with a sliding door in a state in which the server main door is opened and the auxiliary door is closed according to the present invention.
13 is a circuit block diagram for monitoring server damage according to the present invention.
14 is a block diagram of a flame discharge configuration for removing harmful air of the present invention.
15 is a first operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of the present invention.
16 is a second operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of the present invention.
17 is a third operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of 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, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a 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 overall contents of 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 the functional configuration that must 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 prior art 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, the following examples will be used by appropriately modifying terms so that those of ordinary skill in the art to which the present invention pertains can be clearly understood in order to efficiently describe the key 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 pertains. 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 a 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 a multi-path communication device according to the present invention.

Figure 6 is an exemplary server applied to the present invention.

7 is a state diagram of a server auxiliary door closed and a main door opened according to the present invention.

Figure 8 is a conceptual diagram of the operation of the server main door and the locking lever of the present invention.

9 is a conceptual diagram of the operation of the server auxiliary door and the sliding panel of the present invention.

10 is a diagram showing a relationship between the main door and the auxiliary door when the server main door of the present invention is opened by 90 degrees.

11 is a diagram showing the relationship between the main door and the auxiliary door when the server main door of the present invention is opened by 180 degrees.

12 is a flowchart illustrating an operation of filling the space of the auxiliary door with a sliding door in a state in which the server main door is opened and the auxiliary door is closed according to the present invention.

13 is a circuit block diagram for monitoring server damage according to the present invention.

14 is a block diagram of a flame discharge configuration for removing harmful air of the present invention.

15 is a first operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of the present invention.

16 is a second operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of the present invention.

17 is a third operation diagram of a switching means for supplying spark discharge electricity of the spark discharge circuit of the present invention,

First, referring to FIG. 1, a water and sewage measurement 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 a management server (140).

The water and sewage detection unit 110 installs various sensors in each water and sewage facility to detect the state of the water 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, and an outlet valve to detect whether or not 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), and after receiving the information detected from the water and sewage detection unit (110) in a normal situation, it 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 a lightning strike), after receiving the detected information from the water supply and sewage detection unit 110 , It 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) 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 telecommunication 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 to transmit and receive 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. It is switched off so as 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, The switch is turned off to block the abnormal voltage caused by the lightning strike 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 opening/closing of valves, flow rate, hydraulic pressure, water level of each reservoir, water leakage, etc. collected from water and sewage facilities through a wireless communication network, or water and sewage The presence or absence of an abnormality in 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). This is to prevent network traffic by minimizing power consumption and minimizing data transmitted and received over the air.

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

At both ends of the power line of the emergency storage battery 20, when the constant monitoring terminal 120a is inoperable, a first timer (T1, 30) operated by supplying 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). The b contact (S32) of) 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 inoperable 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.

In this way, the first timer (T1, 30) is for adding 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. In addition, it serves to prevent the emergency monitoring terminal (120b) from operating for negligible failures such as a 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, 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 relays LR1 and 50 and the second latch relays LR2 and 60 are each separately provided with a set (SET) coil and a reset (RST) coil, and are set when a 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 on the 2 power lines 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).

Therefore, 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 operation when the constant monitoring terminal 120a returns to normal in the state in which the first latch relays LR1 and 50 are set.

A contact S60 of the second timers T2 and 40 is connected in series to the reset coils 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, as the contact a (S70, S80) of the latch relays respectively installed in the power line 2 of the emergency monitoring terminal 120b is turned off, the emergency monitoring terminal 120b stops operating.

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 by a mechanical configuration while sharing a water level gauge by electronic sensing together with a constant monitoring terminal.

The buoyant inlet water level meter 150 is connected to the rail 151 through a dovetail-shaped rail groove (151a) having a dovetail-shaped rail groove (151a) installed in the water tank (1) of a water and sewage facility. A float 152 that is mounted to be elevating and floats in the water (water, sewage) filled in the water tank 1, a valve control 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 the contact point of the valve adjustment switch 153 to close the inlet pipe 2 , Consists of 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 an OFF contact at normal times.

The motor 154 receives power from the emergency capacitor 20, and when it is in contact with the valve adjustment switch 153, it receives power and rotates the valve 3. 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 water 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 may be 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 turned on 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 a remote manager can quickly know the rise in the 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 so that 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, the same as the buoyancy-type 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 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 server applied to the present invention needs to double the structure of the door for constant temperature and humidity, and the present invention maintains the constant temperature and humidity function by installing a double door. In addition, all double doors may be opened by one operation, or only one door may be opened by separating them.

That is, the main door 1100 is formed in the shape of a square panel and is closed or opened by separating the inside and the outside of the device, and the main door is installed at a certain distance apart from the main door, but is manufactured in a square panel shape corresponding to the shape of the main door. Includes an auxiliary door 1200 installed horizontally on the main door to separate the interior and exterior of the device, and a door frame 300 that fixes one side of the main door and the auxiliary door and the other side is forced into or opened. It is done by doing.

The main door 1100 includes a door handle 1110, a door handle cover 1120, a cover closing member 1130, a locking lever 1140, a power transmission wire 1150, and a locking bolt It consists of (1160).

The door handle 1110 is installed at the right or left edge of the door, but is installed at the height of the human body, and is installed at a point spaced apart from the edge of the door by a predetermined distance.

The door handle cover 1120 has a shape surrounding the top, bottom, left, and right of the door handle and has a rectangular panel shape that is longer in a horizontal direction than in a vertical direction.

The cover closing member 1130 serves to protect the door handle cover as a member surrounding the upper and lower portions of the door handle cover.

The locking lever 1140 is installed on one side of the door handle cover and consists of a rotary-type handle and a shaft for coupling, and the shaft for coupling the door handle cover is inserted and coupled, and rotates clockwise or counterclockwise. It is determined to be locked or unlocked between the main door and the auxiliary door.

The power transmission wire 1150 is connected to one side of the locking lever, and transmits the power of the locking lever to the outside while rotating corresponding to the rotation of the locking lever clockwise or counterclockwise.

The locking bolt 1160 is coupled to the power transmission wire, but at the same time, it is vertically slidably coupled to the door handle cover, and when the power transmission wire moves by moving the locking lever, it moves up and down in association with the auxiliary door. It is configured to be able to connect or disconnect.

The auxiliary door 1200 includes a guide rail 1210, a sliding panel 1220, a panel finishing member 1230, and a sliding protrusion 1240.

The guide rail 1210 is installed at a certain distance above and below one side of the auxiliary door, but is installed at the point where the door handle and the door handle cover of the main door are located, and a C-shaped channel is installed inside each. The door handle and the door handle cover are coupled or released to induce the main door and the auxiliary door to remain engaged or to be released.

The sliding panel 1220 is inserted or released into the guide rail and flows along the guide rail when only the auxiliary door is separately used to close the space between the guide rail, and when the main door and the auxiliary door are opened and closed at the same time, the guide The space between the rails is opened so that the open state of the space is naturally maintained when the door handle is operated.

The panel finishing member 1230 serves to protect the sliding panel as a member surrounding the upper and lower portions of the sliding panel.

The sliding protrusion 1240 is installed on the upper and lower portions of the sliding panel, assists the sliding panel to move back and forth naturally along the guide rail, and reciprocates the guide rail in a C-shaped channel to the left and right.

Hereinafter, the operation of the present invention will be described.

Looking at the case where the main door 1100 and the auxiliary door 1200 move at the same time, first, the main door 1100 and the auxiliary door 1200 are kept connected to each other, and the door handle cover of the main door 1100 The locking bolt 1160 mounted on the 1110 is inserted and coupled to the guide rail 1210 of the auxiliary door 1200.

That is, since the door handle cover 1120 mounted on the main door 1100 and the guide rail 1210 mounted on the auxiliary door 1200 maintain mutually coupled state, when the main door 1100 is opened, the auxiliary door ( 1200 is opened in response to the movement of the main door 1100, and when the main door 1100 is closed, the auxiliary door 1200 is closed according to the movement of the main door 1100.

At this time, the door handle cover 1120 of the main door 1100 slides along the guide rail 1210, and specifically, the locking bolts 1160 installed at the upper and lower ends of the door handle cover 1120 are guide rails. It moves to the right along (1210).

And, looking at the closing operation of the main door 1100, when the main door 1100 is closed, the hinge is operated so that the main door 1100 is closed at a certain angle around the door frame 1300, and the auxiliary door 1200 is hinged at the same time. It flows around and is closed at the same angle as the closing angle of the main door 1100.

At this time, the door handle cover 1120 of the main door 1100 slides along the guide rail 1210, and specifically, the locking bolts 1160 installed at the upper and lower ends of the door handle cover 1120 are guide rails. It moves to the left along (1210).

Accordingly, since the main door 1100 and the auxiliary door 1200 continue to be connected, the auxiliary door 1200 is opened or closed only by opening and closing the door handle 1110 of the main door 1100, making operation more convenient. Do.

That is, when the door handle 1110 of the main door 1100 is opened, the auxiliary door 1200 is automatically opened, and when the door handle 1110 of the main door 1100 is closed, the auxiliary door 1200 is automatically closed. It is possible to use the auxiliary door 1200 easily, and when using the auxiliary door 1200 to maximize the effect of temperature preservation, only the door handle 1110 of the main door 1100 needs to be operated, so that the convenience in use can be maximized. .

Meanwhile, a case in which the main door 1100 and the auxiliary door 1200 are separately moved will be described as follows.

When the main door 1100 and the auxiliary door 1200 are used separately, the locking lever 1130 mounted on the door handle 1110 of the main door 1100 is operated. Then, the power transmission wire 1150 connected to the locking lever 1140 operates, and accordingly, the locking bolt 1160 connected to the power transmission wire 1150 operates, and the guide rail installed on the auxiliary door 1200 The main door 1100 is separated from 1210.

That is, when the locking lever 1140 is operated, the locking bolt 1160 is moved to the central axis of the door handle cover 1120 and is removed from the guide rail 1210. At this time, when the main door 1100 is moved, the main door The 1100 and the auxiliary door 1200 are completely separated.

Thereafter, since the space portion 1211 is formed in the center of the guide rail 1210 of the auxiliary door 1200, the sliding panel 1220 is moved to the right to close it. At this time, the sliding panel 1220 is installed above and below the sliding panel 1220. Since the protrusion 1240 moves along the guide rail 1210, it may flow more easily.

In addition, when the movement of the sliding panel 1220 is completed as described above, the space 1211 existing between the guide rails 1210 of the auxiliary door 1200 is completely filled, and accordingly, the auxiliary door 1200 is completely filled. When used as a transparent window, the entire auxiliary door 1200 can be completely closed.

On the other hand, in the present invention, a conductor 2 for detecting damage to the server is attached to the server body, and when a crack occurs in the server body and is damaged, an alarm is output through a lamp or speaker.

In other words, the present invention supplies current to the conductor (VCC, GND), and when the crack is a little deeper due to damage to the part where the conductor 2 is installed, the conductor 2 is short-circuited to block the flow of current. This is to be recognized by the detection means (1) and output an alarm signal to the outside.

Referring to the drawings of the present invention, it comprises a server damage detection means (1), an alarm output means (3), and a current drive control unit (4).

The server damage detection means (1) is connected to the current path between the power supply voltage (VCC) and the ground voltage (GND), and when a crack occurs, the conductor 2 is short-circuited to block the current flow and cut off the power supply voltage (VCC). It is configured to detect the abnormality of damage by preventing pull-down, and the alarm output means 3 sets a predetermined power voltage VCC when the server damage detection means 1 detects damage due to a crack in the server. It is configured to generate an alarm signal by being applied, and the current drive control unit 4 is switched by receiving a predetermined power voltage as the server damage detection means 1 is short-circuited, and the power voltage ( VCC).

In addition, the current drive control unit 4 receives a predetermined power supply voltage (VCC) as the server damage detection means (1) is short-circuited, the first electronic contact means (5) for switching to form a current path, and the As the first electromagnetic contact means 5 conducts, it is switched by receiving a predetermined current and is composed of a second electromagnetic contact means 6 which forms a current path to the alarm output means 3.

Meanwhile, the first electromagnetic contact means 5 is preferably a transistor element, and the second electromagnetic contact means 6 is preferably a relay element, but other electromagnetic contact elements may be used depending on the circuit configuration.

Looking at the overall operation of the present invention configured as described above with reference to the drawings as follows.

When the server damage detection means (1) installed between the power voltage (VCC) and the ground voltage (GND) short-circuits the conductor (2), which is a detection means, due to damage due to a crack in the server, the potential of the first node (Nd1) is A high voltage is formed at the input terminal of the first electromagnetic contact means 21 due to the rise to the potential of the power voltage VCC and the elevated potential to turn on the electromagnetic contact means.

The current path of the input end of the second electromagnetic contact means 6 is also conducted due to the current path formed when the first electromagnetic contact means 5 is turned on, and is applied to the input end of the second electromagnetic contact means 6 A strong magnetic field is formed due to the applied current, and the electric low contact means of the output terminal is switched due to the magnetic field.

Due to the conduction of the output terminal of the second electronic contact means 6, the alarm output means 3 is supplied with a predetermined power supply voltage (VCC) to generate an alarm signal, and the operator can take appropriate measures according to the server crack. There will be.

Of course, when the crack in the area where the server damage detection means (1) is installed is no longer intensified, the power supply voltage (VCC) is ground voltage through the conductor (2), which is a detection means, because the conductor (2) remains connected. Since both are pulled down to (GND), the first and second electronic contact means 5 and 6 are turned off, and the alarm signal 3 is not generated.

On the other hand, the presence of contaminated air around the server can adversely affect the server, so the contaminated air is burned away so that the server area is protected from contamination sources.

That is, a contaminated air burner is additionally installed on one side of the server to remove contaminated air discharged to the outside, and the device is configured to burn out harmful substances by igniting a spark by spark discharge.

The flame discharge re-ignition switching means 2222 is further attached to the switching means 2221 for supplying spark discharge electricity of the contaminated air burner part 2000, and the spark discharge re-ignition switching means 2222 is re-ignited. The spark discharge re-ignition circuit unit 2223 is installed so as to be contacted, and the end of the spark discharge re-ignition circuit unit 2223 is connected to an electrical output terminal.

That is, in the present invention, when the spark discharge re-ignition switching means 2222 is operated when the spark discharge electricity supply switching means 2221 is operated, the initial spark discharge is ignited, and then the spark discharge is caused by external wind or If it is turned off due to moisture, the flame discharge re-ignition circuit unit 2223 interlocked with the flame discharge re-ignition switching means 2222 operates to re-ignite the flame discharge to prevent the flame discharge from being turned off.

That is, when the switching means 2221 for supplying spark discharge electricity is rotated, the spark discharge re-ignition switching means 2222 simultaneously rotates to turn on the spark discharge re-ignition circuit part 2223, and accordingly, the spark discharge re-ignition circuit part ( As the discharge electrode connected to the output terminal of 2223) is ignited, electricity is ignited. When ignited by the discharge electrode, the power supplied to the discharge electrode is turned off, so that no more discharge occurs.

And, at this time, since the spark discharge re-ignition switching means 2222 maintains the switching state, the spark discharge re-ignition circuit unit 2223 continues to operate, and accordingly, the spark of spark discharge due to external wind or moisture. When this is turned off, the spark discharge re-ignition circuit part 2223 automatically operates to ignite the discharge electrode again to ignite the spark discharge, so that the spark caused by the spark discharge is continuously maintained.

In the drawing, reference numeral 2201 denotes a power supply unit, 2210 denotes a power supply control unit, and 2220 denotes a power supply line. At this time, when the switching means 2221 for supplying spark discharge electricity is rotated, electricity for spark discharge is supplied to generate spark discharge sparks.

In the present invention, the spark discharge re-ignition switching means (2222) is coupled to the spark discharge electricity supply switching means (2221), and the spark discharge re-ignition switching means (2222) is activated when the spark discharge electricity supply switching means (2221) is operated. The main feature is to switch the spark discharge re-ignition circuit part 2223 while operating.

That is, in the present invention, when the switching means 2221 for supplying spark discharge electricity is operated, the spark discharge re-ignition switching means is operated by mechanically touching the spark discharge re-ignition circuit part 2223 to operate.

The spark discharge re-ignition switching means 2222 of the present invention is composed of a pinion gear 2222a, a first sliding conveying member 2222b, a second sliding conveying member 2222c, and a tension spring 2222d.

The pinion gear 2222a is installed on the edge of the switching means 2221 for supplying spark discharge electricity and rotates simultaneously when the switching means 2221 for supplying spark discharge electricity rotates.

The first sliding transfer member 2222b has a cylindrical or square column shape so as to slide horizontally by rotation of the pinion gear 2222a, and a rack gear 2222e is formed on a contact surface with the pinion gear 2222a.

The second sliding transfer member 2222c is coupled to the inner side of the first sliding transfer member 2222b, and when the first sliding transfer member 2222b moves, it interlocks with it to switch the spark discharge re-ignition circuit part 2223.

The tension spring 2222d is connected to the end of the first sliding transfer member 2222b and the start of the second sliding transfer member 2222b, respectively, and serves to maintain the switching state of the spark discharge re-ignition circuit unit 2223. .

Hereinafter, the operation of the spark discharge re-ignition switching means 2222 will be described.

When the spark discharge electricity supply switching means 2221 is rotated to ignite the spark discharge, the pinion gear 2222a formed on the edge of the spark discharge electricity supply switching means 2221 rotates.

When the pinion gear 2222a rotates, the rack gear 2222e of the first sliding transfer member 2222b moves, and the first sliding transfer member 2222b moves to the right.

Then, the second sliding transfer member 2222c is coupled to the inner side of the first sliding transfer member 2222b to move the spark discharge re-ignition circuit unit 2223 to switch.

Thereafter, when the switching means for supplying spark discharge electricity is continuously rotated to increase the amount of electricity supplied to increase the spark discharge spark, the first sliding transfer member 2222b continues to move to the right, and at this time, the second sliding transfer member 2222c Since is in a state of being touched on the spark discharge re-ignition circuit, the tension spring is stretched so that the second sliding transfer member 2222c does not move any more.

That is, even if the pinion gear is continuously rotated by continuously rotating the switching means 2221 for supplying spark discharge electricity, the second sliding transfer member 2222c does not move and only keeps the switching state of the spark discharge re-ignition circuit part 2223. It is to let you do.

In addition, when the switching means for supplying spark discharge electricity (2221) is rotated in reverse to reduce the spark discharge spark, the first sliding transfer member (2222b) moves to the left, and at this time, the tension spring (2222d) operates. The transfer member 2222c does not move and keeps the switching state of the spark discharge re-ignition circuit unit 2223.

Thereafter, when the switching means 2221 for supplying spark discharge electricity is completely turned, the second sliding conveying member 2222c moves along the first sliding conveying member 2222b to turn off the switching of the spark discharge re-ignition circuit part 2223. Will be ordered.

Hereinafter, a detailed configuration of the spark discharge re-ignition circuit unit 2223 applied to the present invention will be described.

The spark discharge re-ignition circuit unit of the present invention includes a DC power supply unit 2101, a spark discharge re-ignition switch 2102, an oscillation booster circuit part 2103, a switching part 2108 for supplying electricity to a discharge electrode, and a high voltage booster circuit part ( 2107), high-pressure discharge spacers 2113a and 2113b, a discharge electrode 2114, and a switching part 2118 for discharging electrode off.

The DC power supply unit 2101 is installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries, or general batteries in series.

The spark discharge re-ignition switch 2102 has one end connected to the DC power supply, and is switched on when the spark discharge re-ignition switching means is rotated.

When the spark discharge re-ignition switch is turned on, the oscillation boosting circuit unit 2103 is supplied with electricity and outputs a boosted AC current.

The discharge electrode electricity supply switching unit 2108 is connected to the output terminal of the oscillation booster circuit unit and is turned on by electric supply.

The high voltage boosting circuit unit 2107 is installed at the output terminal of the switching unit for supplying electricity to the discharge electrode and generates a high voltage.

The high-pressure discharge spacers 2113a and 2113b are formed by connecting high-voltage power supplied by a high-voltage boosting circuit.

The discharge electrode 2114 is ignited while being discharged using a power provided by a high-pressure discharge spacer to induce a spark to be generated.

The discharge electrode blocking switching unit 2118 is connected to the discharge electrode and the base end, and the emitter end and the collector end are connected to the oscillation transformer and the switching unit for supplying electricity to the discharge electrode. It is switched while forming a closed circuit and cuts off the power to the switching unit for discharging electrode electricity supply to block the discharging electrode from being ignited. Accordingly, it serves to induce the discharge electrode to be ignited by turning on power to the switching unit for supplying electricity to the discharge electrode.

Hereinafter, the operation of the spark discharge re-ignition circuit unit will be described.

First, when the spark discharge re-ignition switch 2102 is turned on, the DC power supply 2101 is connected to supply power to the oscillation booster circuit part 2103, and a high voltage is applied to the secondary side of the oscillation booster circuit part 2103.

The power induced in the secondary side becomes a half-wave DC power through the rectifier diode 2106, and this half-wave DC power becomes a more stable DC power source due to the charging/discharging action of the capacitor 2121.

This DC power is applied to the anode end of the thyristor (discharge electrode switching unit 2108) through the primary coil of the high voltage booster circuit unit 2107, while this DC power is charged to the capacitor 2110 through a resistor. . The increased voltage passes through the diak 2111 and triggers the discharge electrode switching unit 2108 so that the anode end and the cathode end are switched so that the operation of the high voltage trans booster circuit unit 2107 is performed, and accordingly, the high voltage is boosted. A high voltage voltage is induced in the secondary coil of the circuit unit 2107, and the induced high voltage causes a secondary discharge between the discharge spacers 2113a and 2113b and spark discharge between the discharge electrodes 2114.

This spark discharge causes an ignition function in the space located between the discharge electrodes 2114. When the space is ignited in this way, an induced voltage is generated by hot electrons at both ends of the discharge electrode by the spark.

The induced voltage induces a closed circuit at the emitter terminal and collector terminal of the discharge electrode blocking switching unit 2118 while activating the base terminal of the discharge electrode blocking switching unit 2118 to turn off the power to the switching unit for supplying electricity to the discharge electrode. Will be ordered.

That is, the voltage between the resistor 2119 and the capacitor 2110 flows through the diode 2120 between the emitter terminal and the collector terminal of the switching unit 2118 for discharging electrode off and is bypassed. ) And the condenser 2110 decreases, and when the voltage between the resistor 2109 and the condenser 2110 decreases, the trigger signal directed to the switching unit 108 for supplying electricity to the discharge electrode is stopped. As the stage and the casing stage are turned off, current does not flow in the primary coil and the secondary coil of the high-voltage booster circuit unit 2107, so that the spark discharge between the discharge electrodes is stopped.

If the spark discharge action is stopped due to the influence of external wind, etc., the flow of current before flowing by hot electrons at both ends of the discharge electrode 2114 disappears, and by doing so, the emitter end and the base of the switching unit 2118 for blocking the discharge electrode Since the bias voltage flowing between the stages disappears, the switching unit 2118 for blocking the discharge electrode is turned off.

As the discharge electrode blocking switching unit 2118 is turned off, the bypass voltage between the resistor 2109 and the capacitor 2110 through the diode 2120 disappears, and this voltage is charged in the capacitor 2110.

This charged voltage causes a break-over phenomenon of the diak 2111, and the diac sends a trigger signal to the switching unit 2108 for supplying electricity to the discharge electrode to start the spark discharge again.

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: terminal for constant monitoring,
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 (6)

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 there is a leak, 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 supply and sewage facility by installing an outflow valve detector for detecting whether or not the outflow valve is opened or closed;
It is connected to the water supply and sewage detection unit, and under normal circumstances, the flow rate detected from the water supply and sewage detection unit, water level, leakage, water quality, inlet valve open or closed, outlet valve open or closed, and a constant monitoring terminal for collecting information on abnormalities in water supply and sewage facilities. ;
An emergency monitoring terminal connected to the water supply and sewerage 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 that is operated by turning on the power of the emergency capacitor when the constant monitoring terminal is inoperable;
A first latch relay for switching and controlling the power of the emergency capacitor 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;
A management server for managing status information of water and sewage facilities transmitted from the constant monitoring terminal or the emergency monitoring terminal;
A main door installed at the entrance door of the server and closed or opened by separating the inside and the outside of the device;
An auxiliary door installed to be spaced apart from the main door by a predetermined distance, manufactured in the shape of a square panel corresponding to the shape of the main door, and installed horizontally on the main door to separate the inside and the outside of the device;
And a door frame for fixing one side of the main door and the auxiliary door and the other side to be in a forced fitting or open state;

The main door 1100,
A door handle 1110 installed at one edge of the thermo-hygrostat, but installed at a height of the human body and spaced a predetermined distance from the edge of the door;
A door handle cover (1120) formed in a rectangular panel shape that covers the top, bottom, left, and right of the door handle and has a longer horizontal direction than a vertical direction;
A cover closing member (1130) for protecting the door handle cover as a member surrounding the upper and lower portions of the door handle cover;
It is installed on one side of the door handle cover and consists of a rotary-type handle and a shaft for coupling, but the shaft for coupling the door handle cover is inserted and coupled, and rotates clockwise or counterclockwise to separate the main door and the auxiliary door. A locking lever 1140 for determining to be in a locked state or an unlocked state;
A power transmission wire (1150) connected to one side of the locking lever and rotating in correspondence with the rotation of the locking lever in a clockwise or counterclockwise direction to transmit the power of the locking lever to the outside;
It is made by being coupled to the power transmission wire, but at the same time, it is vertically sliding to the door handle cover, and when the power transmission wire is moved by moving the locking lever, it is linked to the auxiliary door or disconnected while moving up and down in connection with it. Water and sewage measurement and control system using a multi-path communication device, characterized in that it comprises a fixed bolt (1160). delete The method of claim 1,
The auxiliary door 1200,
It is installed at a certain distance apart from the main door, but is installed at the point where the door handle and door handle cover of the main door are located, and a C-shaped channel is installed inside each, and the door handle and door handle cover are combined or released. A guide rail (1210) for inducing the main door and the auxiliary door to maintain a combined or released state;
When only the auxiliary door is used separately by being inserted or released into the guide rail, it flows along the guide rail to close the space between the guide rail, and when the main door and the auxiliary door are opened and closed at the same time, the space between the guide rail is A sliding panel 1220 for inducing an open state of the space portion to be naturally maintained by opening the door handle;
A panel finishing member 1230 for protecting the sliding panel as a member surrounding the upper and lower portions of the sliding panel;
It is installed on the upper and lower portions of the sliding panel, and assists the sliding panel to move forward and backward naturally along the guide rail, and comprises a sliding protrusion 1240 for reciprocating the guide rail in a C-shaped channel left and right. Water and sewage measurement control system using route communication device. delete delete The method of claim 1,
At one end of the server, the contaminated air burner is further installed,
The contaminated air burner part,
A switching means (2221) for supplying spark discharge electricity; A spark discharge re-ignition switching means (2222) for automatically re-igniting the spark discharge by being mounted on the spark discharge electricity supply switching means (2221); A spark discharge re-ignition circuit unit 2223 connected to the spark discharge re-ignition switching means 2222 and outputting a signal for re-ignitioning the spark discharge is installed;

The spark discharge re-ignition switching means (2222),
A pinion gear (2222a) installed on the edge of the switching means (2221) for supplying spark discharge electricity and rotating at the same time when the switching means (2221) for supplying spark discharge electricity is rotated;
A first sliding transfer member (2222b) formed by forming a rack gear (2222e) on a contact surface with the pinion gear (2222a) and having a cylindrical or square column shape so as to slide horizontally by the rotation of the pinion gear (2222a);
A second sliding transfer member (2222c) that is coupled to the inner side of the first sliding transfer member (2222b) and moves in conjunction with the first sliding transfer member (2222b) to switch the spark discharge re-ignition circuit unit (2223);
A tension spring 2222d, which is connected to the end of the first sliding transfer member 2222b and the start of the second sliding transfer member 2222b, and serves to maintain the switching state of the spark discharge re-ignition circuit part 2223. Including;

The spark discharge re-ignition circuit part 2223,
A DC power supply unit 2101 installed to supply a required voltage by connecting a plurality of 12 volt lithium batteries, vehicle storage batteries or general batteries in series;
A spark discharge re-ignition switch (2102) which has one end connected to the DC power supply and is switched on when the spark discharge re-ignition switching means is rotated;
An oscillation booster circuit part 2103 for outputting a boosted AC current by supplying electricity when the spark discharge re-ignition switch is turned on;
A switching unit 2108 for supplying electricity to a discharge electrode connected to the output terminal of the oscillation booster circuit unit and turned on by electric supply;
A high-voltage boosting circuit part 2107 installed at an output terminal of the switching part for supplying electricity to the discharge electrode and generating a high voltage;
A high-pressure discharge spacer (2113a, 2113b) formed by connecting a high-voltage power supply supplied by the high-voltage boosting circuit unit;
A discharge electrode (2114) for inducing a flame to burn by igniting the discharge while being discharged using the power provided by the high-pressure discharge spacer;
The discharge electrode and the base end are connected, the emitter end and the collector end are connected to the oscillation transformer and the switching unit for ignition of the discharge electrode, and when a spark is generated in the space, it is switched while forming a closed circuit by hot electrons, and the discharge electrode is switched for electricity supply. The power to the negative electrode is cut off to prevent the discharge electrode from being ignited, and when the spark discharge flame is turned off by external wind or moisture, the closed circuit is broken due to the extinction of the hot electrons and the switching is turned off. Accordingly, the power to the switching unit for supplying electricity to the discharge electrode is turned off. Water and sewage measurement control system using a multi-path communication device, characterized in that it comprises a switching unit (2118) for blocking the discharge electrode that functions to induce the discharge electrode to be ignited by turning it on.

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