KR102642573B1 - Power line monitoring and safety management system for power facilities within the power district - Google Patents

Abstract

The present invention provides a power line monitoring and safety management system for power facilities in a power district. The power line monitoring and safety management system of the power equipment in the power conduit includes a power line protection unit disposed inside the power conduit and having protective pipes in which each of the power lines is disposed, and disposed on each of the protective pipes, Power measurement sensors that measure the power value flowing from each of the power lines, and are provided in each of the protection tubes, and set the internal temperature and internal humidity of the protection tubes to a preset standard so that the measured power value achieves a preset reference power value. It includes a temperature and humidity variable unit that variably sets the temperature and reference humidity.

Description

Power line monitoring and safety management system for power facilities within the power district}

The present invention relates to a power line monitoring and safety management system for power facilities in a power district. More specifically, it stably protects power lines within a power district and prevents power lines from being damaged by fire occurring inside the power district. It concerns a power line monitoring and safety management system for power facilities within a power conduit that can prevent damage.

Typically, a power conduit is a structure buried underground to connect power facilities, and components of power facilities such as power lines, power cables, and transformers are placed there. Power outlets play an important role in the stable operation of power facilities.

Power conduits are generally made of concrete structures, and protective pipes are installed inside to arrange the components of power facilities. Protective pipes serve to protect components of power facilities from external shock, fire, and flooding.

In the configuration in which the power line of the power facility is arranged in the power conduit, the power line of the power facility in the power conduit is generally arranged parallel to the inside of the protection pipe. A power line is a cable that transmits power, and wires are inserted inside. Wires are made of copper or aluminum and serve to conduct current.

When the power line is placed inside the protection tube, it is fixed at regular intervals to prevent the power line from being damaged from electrical or mechanical shock.

However, if the power transmitted through each power line in a conventional power outlet is abnormal, a fire may occur due to internal electrical and mechanical shock. If a fire occurs, components of power equipment may be damaged and power supply may be interrupted.

In the case of electrical shock, a fire may occur due to a short circuit in the power line, a short circuit, or a spark. A short circuit is a phenomenon in which electric current flows when wires touch each other, and a short circuit is a phenomenon in which electric current flows when the insulation of a wire is removed. A spark occurs when a wire is short-circuited or leaks.

Republic of Korea Patent No. 10-1084664 (registration date: November 11, 2011)

The present invention was devised to solve the above-mentioned problems, and the purposes of the present invention are as follows.

The present invention can stably protect the power lines within the power outlet and prevent the power lines from being damaged by fire occurring inside the power outlet, as well as adjust the temperature of each power line contained in each protection tube. It is monitored in real time for each unit of length, and when a section with an abnormal temperature is detected, the gel-like refrigerant supplied through the internal flow path of the protection pipe is sprayed into the section to suppress the occurrence of fire, and the refrigerant is recovered after cooling. In addition, the purpose is to provide a power line monitoring and safety management system for power facilities in the power district that can spray and retrieve fire extinguishing agents for fire suppression in the section when the temperature in the section reaches the fire temperature.

The object of the present invention is not limited to the object mentioned above, and other objects and advantages of the present invention that are not mentioned can be understood through the following description and will be more clearly understood by the examples of the present invention. Additionally, it will be readily apparent that the objects and advantages of the present invention can be realized by the means and combinations thereof indicated in the patent claims.

In order to achieve the above objectives, the present invention provides a power line monitoring and safety management system for power facilities in a power district.

The power line monitoring and safety management system of the power equipment in the power district includes a fire detection sensor unit that detects fire occurring in each of the power lines arranged inside the power district, and each of the power lines inside the power district. A power line protection unit having protective tubes disposed therein, power measurement sensors disposed on each of the protective tubes to measure a power value flowing in each of the power lines, and provided in each of the protective tubes, wherein the measured It includes a temperature and humidity variable unit that variably sets the internal temperature and internal humidity of the protective tubes so that the power value reaches a preset reference power value.

The power line protection unit includes a support plate installed on an inner side of the power conduit and supporting the protection pipes,

Each of the protective tubes includes a tube body extending through a hollow body so that the power lines are located inside, extending from the inner periphery of the tube body along the central axis of the tube body, and having an extended end surrounding the power line at a plurality of positions. It includes support members that elastically support.

Here, partition plates are installed inside each of the protective pipes,

A through hole through which the power line passes is formed in the partition plates,

An airtight member is installed on the inner circumference of the through hole to elastically contact and airtight the outer circumference of the power line,

In each of the protective tubes, unit spaces are formed by the partition plates,

A heater is installed inside each of the protective pipes corresponding to each of the unit spaces, and the heater is connected to a current provider that heats the heater to a certain temperature by providing current to the heater under control of the controller. ,

Each of the protection pipes corresponding to each of the unit spaces is connected to an outside air inlet pipe and an outside air outlet pipe, and a fan that introduces outside air is preferably installed in the outside air inlet pipe.

And the temperature and humidity variable part,

It includes temperature sensors, humidity sensors, a supply pump, a recovery pump, a refrigerant provider for supplying refrigerant, and a controller,

The temperature sensors are installed in the protection pipes to measure the internal temperature in each of the unit spaces,

The humidity sensors are installed in the protection tubes to measure internal humidity in each of the unit spaces,

Each of the protection pipes corresponding to each of the unit spaces is connected to a supply line and a recovery line,

One end of the supply line is connected to each of the unit spaces, and the other end is connected to the refrigerant provider,

The supply pump is installed on the supply line to provide refrigerant to each of the unit spaces through the supply line,

One end of the recovery line is connected to each of the unit spaces, and the other end is connected to the refrigerant provider,

The recovery pump is installed on the recovery line to recover the refrigerant supplied to each of the unit spaces through the recovery line to the refrigerant provider,

The controller is,

Among the unit spaces, the power value measured through the power measurement sensors exceeds the reference power value,

Among the unit spaces, a space where the internal temperature measured through the temperature sensors is higher than a preset fire risk temperature is set as an ideal space,

The refrigerant is supplied from the refrigerant provider to the ideal space using the supply pump,

The temperature measured in the ideal space is below the fire danger temperature,

When the measured power value reaches the reference power value, it is recommended to use the recovery pump to recover the supplied refrigerant to the refrigerant provider.

In addition, a second cooling coil is installed in the recovery line,

The controller is,

Using a third current provider, a third current is provided to the second cooling coil to achieve a constant cooling temperature, thereby cooling the recovered refrigerant to a preset reference cooling temperature,

The second cooling coil is externally wrapped from one end to the other end of the recovery line,

In the recovery line,

It is desirable to install a filter to filter out foreign substances contained in the recovered refrigerant.

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Through the above problems, the present invention can stably protect the power lines within the power outlet and prevent the power lines from being damaged by fire occurring inside the power outlet, as well as the power lines accommodated in each protection tube. The temperature of each section is monitored in real time by a certain length unit, and when a section with an abnormal temperature is detected, the gel-like refrigerant supplied through the internal passage of the protection pipe is sprayed into the section to suppress the occurrence of fire, and then cooled. In addition to recovering the refrigerant, when the temperature in the section reaches the fire temperature, it has the effect of spraying and recovering a fire extinguishing agent for fire suppression in the section.

In addition to the above-described effects, specific effects of the present invention are described below while explaining specific details for carrying out the invention.

Figure 1 is a diagram showing the power line monitoring and safety management system of power equipment in the power conduit of the present invention.
Figure 2 is a perspective view showing the arrangement of the protection tube according to the present invention.
Figure 3 is a cross-sectional view showing a state in which a power line is disposed inside the protection tube according to the present invention.
Figure 4 is a side cross-sectional view showing the protective tube according to the present invention.
Figure 5 is an enlarged cross-sectional view showing an example of refrigerant being supplied and recovered to an ideal space among unit spaces.
Figure 6 is an enlarged longitudinal cross-sectional view showing an example of refrigerant being supplied and recovered to an ideal space among unit spaces.
Figure 7 is a diagram showing an example in which a second cooling coil is buried in a recovery line.

The above-described objects, features, and advantages will be described in detail later with reference to the attached drawings, so that those skilled in the art will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of known techniques related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings. In the drawings, identical reference numerals are used to indicate identical or similar components.

Although first, second, etc. are used to describe various components, these components are of course not limited by these terms. These terms are only used to distinguish one component from another component, and unless specifically stated to the contrary, the first component may also be a second component.

Hereinafter, the “top (or bottom)” of a component or the arrangement of any component on the “top (or bottom)” of a component means that any component is placed in contact with the top (or bottom) of the component. Additionally, it may mean that other components may be interposed between the component and any component disposed on (or under) the component.

Additionally, when a component is described as being “connected,” “coupled,” or “connected” to another component, the components may be directly connected or connected to each other, but the other component is “interposed” between each component. It should be understood that “or, each component may be “connected,” “combined,” or “connected” through other components.

Throughout the specification, unless otherwise stated, each element may be singular or plural.

As used herein, singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, terms such as “consists of” or “comprises” should not be construed as necessarily including all of the various components or steps described in the specification, and some of the components or steps may include It may not be included, or it should be interpreted as including additional components or steps.

Hereinafter, the power line monitoring and safety management system of power equipment in the power outlet according to the present invention will be described with reference to the attached drawings.

Figure 1 is a diagram showing the power line monitoring and safety management system of power equipment in the power conduit of the present invention. Figure 2 is a perspective view showing the arrangement of the protection tube according to the present invention. Figure 3 is a cross-sectional view showing a state in which a power line is disposed inside the protection tube according to the present invention.

Referring to FIGS. 1 to 3, the power line monitoring and safety management system of the power equipment in the power conduit of the present invention is disposed inside the power conduit (1), and each of the power lines (10) is a protective tube disposed inside. A power line protection unit 100 having a power line protection unit 100, power measurement sensors 200 disposed on each of the protection pipes 110 and measuring the power value flowing in each of the power lines 10, A temperature and humidity variable is provided in each of the protective tubes 110 and variably sets the internal temperature and internal humidity of the protective tubes 110 so that the measured power value achieves a preset reference power value. Includes part 30.

The power line protection unit 100 is installed on the inner side of the power conduit 1 and includes a support plate 120 that supports the protection tubes 110.

The protection tube 110 is installed by fitting into the groove 121 formed at the upper end of the support plate 120.

The support plate 120 may be installed at intervals on the inner side wall of the power bulb 1, or may be installed on the upper and lower walls.

Each of the protective pipes 110 includes a hollow first pipe body 110-1, a second pipe body 110-2 disposed in the hollow of the first pipe body 110-1, and a first pipe body 110-1. It has support members 112-1 and second support members 112-2.

The first support members 112-1 elastically support a plurality of positions on the inner circumference of the first pipe body 110-1 and a plurality of positions on the outer circumference of the second pipe body 110-2.

The second support members 112-2 elastically support a plurality of positions on the inner circumference of the second pipe body 110-2 and a plurality of circumferences of the power lines 10.

The power line 10 is disposed in the hollow of the second pipe body 110-2.

Each of the first and second support members 112-1 and 112-2 is composed of multi-stage pipes with elastic springs (not shown) installed therein to enable elastic flow.

A first elastic member (112a) is installed at each end of the first support members (112-1), and the first elastic member (112a) is partially inserted around the first pipe body (110-1). It is fixed.

A second elastic member 112b is formed at the ends of the second support members 112-2 to surround a portion of the circumference of the power line 10 and elastically grip the power line 10.

The power line monitoring and safety management system of power equipment in the power conduit of the present invention has the following actions and effects.

The power line protection unit 100 supports and protects the power line 10 by installing the protection tubes 110 into the support plate 120. The power measurement sensors 200 measure the power value flowing in the power line 10 and transmit it to the temperature and humidity variable unit 30. The temperature and humidity variable unit 30 variably sets the internal temperature and internal humidity of the protective tubes 110 to a preset reference temperature and reference humidity so that the measured power value achieves a preset reference power value.

The power line protection unit 100 protects the power line 10 from external shock and vibration through the protection pipes 110, thereby preventing damage to the power line and improving the stability of power supply.

The power measurement sensors 200 measure the power value flowing in the power line 10 in real time, allowing quick detection of abnormalities in the power line.

The temperature and humidity variable unit 30 maintains normal operation of the power line by appropriately controlling the internal temperature and internal humidity of the protection pipes 110 according to the power value of the power line 10.

Figure 4 is a side cross-sectional view showing the protective tube according to the present invention. Figure 5 is an enlarged cross-sectional view showing an example of refrigerant being supplied and recovered to an ideal space among unit spaces. Figure 6 is an enlarged longitudinal cross-sectional view showing an example of refrigerant being supplied and recovered to an ideal space among unit spaces.

Referring to Figures 4 to 6, partition plates 130 are installed inside each of the protection tubes 110.

A through hole 131 through which the power line 10 passes is formed in the partition plates 130.

An airtight member (not shown) is installed on the inner circumference of the through hole 131 to elastically contact and airtight the outer circumference of the power line 10.

In each of the protective tubes 110, unit spaces are formed by the partition plates 130.

A heater 140 is installed inside each of the protection tubes 110 corresponding to each of the unit spaces, and the heater 140 provides current to the heater 140 under the control of the controller 600. Thus, the heater 140 is connected to a current provider 141 that heats the heater 140 to a certain temperature. The heater 140 is disposed inside the second pipe body 110-2.

Each of the protection pipes 110 corresponding to each of the unit spaces is connected to an outside air inlet pipe 150 and an outside air outlet pipe 160, and the outside air inlet pipe 150 has a fan 151 for introducing outside air. It is installed. The outside air inlet pipe 150 and the outside air outlet pipe 160 are connected to the hollow of the second pipe body 110-2.

The temperature and humidity variable unit 30 includes temperature sensors 310, humidity sensors 320, a supply pump 330, a recovery pump 340, and a refrigerant provider 350 that supplies refrigerant, Includes a controller 600.

The temperature sensors 310 are installed in the second pipe bodies 110-2 to measure the internal temperature in each of the unit spaces.

The humidity sensors 320 are installed in the second pipe bodies 110-2 to measure internal humidity in each of the unit spaces.

Each of the second pipe bodies 110-2 corresponding to each of the unit spaces is connected to a supply line 351 and a recovery line 352.

One end of the supply line 351 is connected to each of the unit spaces, and the other end is connected to the refrigerant provider 350.

The supply pump 330 is installed on the supply line 351 and supplies refrigerant to each of the unit spaces through the supply line 351.

One end of the recovery line 352 is connected to each of the unit spaces, and the other end is connected to the refrigerant provider 350.

The recovery pump 340 is installed on the recovery line 352 and recovers the refrigerant supplied to each of the unit spaces through the recovery line 352 to the refrigerant provider 350.

The controller 600 determines whether the power value measured through the power measurement sensors 200 among the unit spaces exceeds the reference power value and through the temperature sensors 310 among the unit spaces. A space where the measured internal temperature is higher than the preset fire danger temperature is set as an abnormal space, and the refrigerant is supplied from the refrigerant provider 350 to the abnormal space using the supply pump 320.

When the temperature measured in the abnormal space is below the fire danger temperature and the measured power value reaches the reference power value, the controller 600 uses the recovery pump 340 to convert the supplied refrigerant into the refrigerant. It is recovered by the provider (350).

Through the above configuration, the power line monitoring and safety management system of the power facility in the power conduit of the present invention has partition plates 130 installed inside each of the protection pipes 110 to form unit spaces, and the unit spaces are formed. A heater 140 is installed in each of them and heated to a certain temperature. In addition, an outside air inlet pipe 150 and an outside air outlet pipe 160 are connected to each of the unit spaces, and a fan 151 is installed in the outside air inlet pipe 150 to introduce outside air. The temperature and humidity variable unit 30 measures the internal temperature and internal humidity of each of the unit spaces through temperature sensors 310 and humidity sensors 320, and transmits the measured values to the controller 600. .

The controller 600 analyzes the measured value, determines that the power value measured through the power measurement sensors 200 among the unit spaces exceeds the reference power value, and detects the temperature sensors 310. The space where the internal temperature measured is above the preset fire risk temperature is set as an ideal space.

For a space set as an ideal space, the controller 600 uses the supply pump 330 to provide the refrigerant from the refrigerant provider 350 to the ideal space. When refrigerant is supplied, the temperature of the abnormal space decreases.

When the temperature of the abnormal space falls below the fire danger temperature and the measured power value reaches the reference power value, the controller 600 uses the recovery pump 340 to supply the supplied refrigerant to the refrigerant. It is recovered by 350.

Through this action, the present invention has the following effects.

If the temperature of the abnormal space rises above the fire danger temperature, the controller 600 immediately supplies refrigerant to lower the temperature. Therefore, it is possible to prevent fire risks before a fire occurs.

Additionally, as the current value of the power line increases, the temperature of the power line increases. As temperatures rise, the insulation of power lines can be damaged, causing short circuits. In order to prevent such a short circuit, the present invention prevents damage to the power line by lowering the temperature of the abnormal space.

Additionally, as the temperature of the power line rises, the resistance of the power line increases. If resistance increases, power loss may increase and the stability of power supply may deteriorate. The present invention reduces such power loss and improves the stability of power supply.

Since the protective tubes of the present invention are divided into unit spaces, each unit space can be managed individually. Therefore, installation and maintenance are easy.

Figure 7 is a diagram showing an example in which a second cooling coil is buried in a recovery line.

Referring to FIG. 7, a second cooling coil 400 is installed in the recovery line 352.

The controller 600 uses the second current provider 410 to provide a second current to the second cooling coil 400 to achieve a constant cooling temperature, thereby adjusting the recovered refrigerant to a preset reference cooling temperature. Cool down.

The second cooling coil 400 extends from one end of the recovery line 352 to the other end.

A filter 353 is installed in the recovery line 352 to filter out foreign substances contained in the recovered refrigerant.

Referring to FIG. 7, a second cooling coil 400 is installed in the recovery line 352, and the controller 600 uses the second current provider 410 to send a second current to the second cooling coil 400. ) to achieve a certain cooling temperature, thereby cooling the recovered refrigerant to a preset reference cooling temperature.

Through this action, the present invention has the following effects.

Enables efficient recycling of refrigerant. Since the recovered refrigerant is a refrigerant used to lower the temperature of the power line, its temperature is bound to be high. If this refrigerant is recycled as is, the temperature of the power line cannot be effectively lowered. The present invention enables efficient recycling of the refrigerant by cooling the recovered refrigerant to a preset reference cooling temperature using a second cooling coil.

The life of the refrigerant can be extended. Refrigerants may deteriorate or be damaged when used at high temperatures. The present invention can extend the life of the refrigerant by cooling the recovered refrigerant to a preset reference cooling temperature using a second cooling coil.

Maintenance costs can be reduced. When refrigerant is used at high temperatures, foreign substances contained in the refrigerant may condense and obstruct the flow of the refrigerant. The present invention installs a filter in the recovery line to filter out foreign substances contained in the recovered refrigerant, thereby maintaining a smooth flow of refrigerant and reducing maintenance costs.

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Through the above-mentioned overall configuration, the present invention can stably protect the power lines within the power outlet and prevent the power line from being damaged by a fire occurring inside the power outlet, as well as the power lines accommodated in each protection tube. The temperature of each power line is monitored in real time for each unit of length, and when a section with an abnormal temperature is detected, the gel-like refrigerant supplied through the internal flow path of the protection pipe is sprayed into the section to suppress the occurrence of fire. , in addition to recovering the refrigerant after cooling, if the temperature in the section reaches the fire temperature, a fire extinguishing agent for fire suppression can be sprayed and recovered in the section.

As described above, the present invention has been described with reference to the illustrative drawings, but the present invention is not limited to the embodiments and drawings disclosed herein, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. It is obvious that transformation can occur. In addition, although the operational effects according to the configuration of the present invention were not explicitly described and explained while explaining the embodiments of the present invention above, it is natural that the predictable effects due to the configuration should also be recognized.

1: Power sphere
30: Temperature and humidity variable part
310: temperature sensor
320: Humidity sensor
330: supply pump
340: recovery pump
350: Refrigerant provider
351: supply line
352: recovery line
353: filter
10: power line
100: Power line protection unit
110: protection tube
110-1: Pipe 1 body
110-2: Pipe 2 body
112-1: First support members
112-2: Second support members
120: support plate
130: partition plate
131: Through hole
140: heater
141: Current provider
150: Outside air inflow pipe
151: fan
160: External air outflow pipe
200: Power measurement sensors
400: 2nd cooling coil
410: Current provider
500: Fire suppression department
510: Fire extinguishing agent supply machine
520: Spray line
530: injection pump
540: Third controller
600: Controller
700: Standby home
710: Unit standby home
720: Rails
730: Linear motor
740: Opening and closing member
2: Main fire extinguishing device

Claims (4)

A power line protection unit disposed inside the power conduit and having protection pipes inside each of the power lines;
Power measurement sensors disposed in each of the protection tubes to measure a power value flowing in each of the power lines; and,
A temperature and humidity variable unit is provided in each of the protective tubes and variably sets the internal temperature and internal humidity of the protective tubes to a preset reference temperature and humidity so that the measured power value achieves a preset reference power value,
The power line protection unit includes a support plate installed on an inner side of the power conduit and supporting the protection pipes,
Each of the protective tubes includes a tube body extending through a hollow body so that the power lines are located inside, extending from the inner periphery of the tube body along the central axis of the tube body, and having an extended end surrounding the power line at a plurality of positions. Includes support members that elastically support,
Dividing plates are installed inside each of the protective pipes,
A through hole through which the power line passes is formed in the partition plates,
An airtight member is installed on the inner circumference of the through hole to elastically contact and airtight the outer circumference of the power line,
In each of the protective tubes, unit spaces are formed by the partition plates,
A heater is installed inside each of the protective pipes corresponding to each of the unit spaces, and the heater is connected to a current provider that heats the heater to a certain temperature by providing current to the heater under control of a controller,
Each of the protection pipes corresponding to each of the unit spaces is connected to an outside air inflow pipe and an outside air outflow pipe, and a fan is installed in the outside air inflow pipe to introduce outside air,
The temperature and humidity variable part,
It includes temperature sensors, humidity sensors, a supply pump, a recovery pump, a refrigerant provider for supplying refrigerant, and the controller,
The temperature sensors are installed in the protection pipes to measure the internal temperature in each of the unit spaces,
The humidity sensors are installed in the protection tubes to measure internal humidity in each of the unit spaces,
Each of the protection pipes corresponding to each of the unit spaces is connected to a supply line and a recovery line,
One end of the supply line is connected to each of the unit spaces, and the other end is connected to the refrigerant provider,
The supply pump is installed on the supply line to provide refrigerant to each of the unit spaces through the supply line,
One end of the recovery line is connected to each of the unit spaces, and the other end is connected to the refrigerant provider,
The recovery pump is installed on the recovery line to recover the refrigerant supplied to each of the unit spaces through the recovery line to the refrigerant provider,
The controller is,
Among the unit spaces, the power value measured through the power measurement sensors exceeds the reference power value,
Among the unit spaces, a space where the internal temperature measured through the temperature sensors is higher than a preset fire risk temperature is set as an ideal space,
The refrigerant is supplied from the refrigerant provider to the ideal space using the supply pump,
The temperature measured in the ideal space is below the fire danger temperature,
A power line monitoring and safety management system for power facilities in a power outlet, characterized in that when the measured power value reaches the reference power value, the supplied refrigerant is recovered to the refrigerant provider using the recovery pump.
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A second cooling coil is installed in the recovery line,
The controller is,
Using a third current provider, a third current is provided to the second cooling coil to achieve a constant cooling temperature, thereby cooling the recovered refrigerant to a preset reference cooling temperature,
The second cooling coil is externally wrapped from one end to the other end of the recovery line,
In the recovery line,
A power line monitoring and safety management system for power facilities in a power outlet, characterized in that a filter is installed to filter out foreign substances contained in the recovered refrigerant.