KR102668984B1 - Underground power line protection pipe structure of a building - Google Patents

Abstract

The present invention provides an underground power line protection pipe structure within a complex. The underground power line protection pipe structure within the complex includes a protection pipe body portion that forms a hollow space inside which power lines are placed and has unit protection pipes connected to corrugated pipes at regular intervals; unit support members installed at predetermined intervals in the hollow of the protection tube body to form unit spaces and through which the power line passes; A sensor unit that measures temperature and humidity in the unit spaces; a ventilation unit connected to the unit spaces and supplying and exhausting outdoor air to the unit spaces; a temperature module unit that controls the temperature inside the unit spaces; And a control unit that controls the operation of the temperature module unit so that the measured temperature reaches a preset reference temperature, and controls the operation of the ventilation unit so that the measured humidity reaches a preset reference humidity.

Description

Underground power line protection pipe structure of a building}

The present invention relates to an underground power line protection pipe structure within a complex, and more specifically, to prevent damage from external shocks such as earthquakes, stably fix power lines, form unit sections divided from each other, and protect pipes for each unit section. This relates to an underground power line protection pipe structure within a complex that can maintain a constant posture and maintain a stable state of the power line by controlling the temperature and humidity of the power line for each unit section in real time.

As industrialization and urbanization progress rapidly, dense areas such as buildings and factories are increasing. In this case, it is not easy to install electrical facilities in the form of overhead transmission to supply electricity to each building, factory, and home.

Due to the difficulty of installing electric facilities, installing electric facilities in the form of underground transmission has recently emerged as an alternative. While underground transmission has the disadvantage of being expensive to install, it has the advantage of being less affected by changes in the natural environment, such as rain, so that it can be maintained safely and improve the reliability of electricity supply.

This underground power transmission involves the process of laying underground cables using any of the underground line construction methods: direct burial, pipeline, and power line. Among the underground line construction methods, the pipeline type is a method of constructing a pipeline using pipes such as synthetic resin pipes, steel pipes, and Hume pipes, and then laying cables. Manholes must be installed at both ends of the pipeline at a certain distance to install and connect cables. .

Pipes such as synthetic resin pipes, steel pipes, and Hume pipes were mainly used for pipeline construction. However, if the ground is soft where the underground transmission cable is installed, the power lines such as underground transmission may be damaged due to ground subsidence. There are many problems such as bending or damage, which not only causes significant disruption in power supply, but also increases maintenance costs because it is underground.

In addition, if part of the power line is damaged inside the pipe that accommodates the power line underground or a fire occurs as a result, there is a problem that cannot be immediately recognized and resolved.

In addition, there is a problem in that it is not possible to check the status of the power line inside the pipeline in real time and immediately resolve the abnormal condition in the relevant section if an abnormal condition occurs.

Republic of Korea Patent No. 10-246656 (registration date: November 8, 2022)

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

The present invention prevents damage from external shocks such as earthquakes, stably fixes power lines, forms unit sections that are divided from each other, maintains a constant posture of the protection tube for each unit section, and maintains the power line for each unit section. The purpose is to provide an underground power line protection pipe structure within the complex that can control temperature and humidity conditions in real time to maintain a stable state of the power line.

In addition, the present invention provides an underground power line protection pipe within the complex that prevents fires by immediately supplying extinguishing materials when the power line rises to an abnormal temperature for each unit section or space, and allows the extinguishing materials to be recovered and reused when the temperature exceeds the ideal temperature. Another purpose is to provide a structure.

The objects of the present invention are not limited to the objects mentioned above, and other objects and advantages of the present invention that are not mentioned can be understood by 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 an underground power line protection pipe structure within the complex.

The underground power line protection pipe structure within the complex includes a protection pipe body portion that forms a hollow space inside which power lines are placed and has unit protection pipes connected to corrugated pipes at regular intervals; unit support members installed at predetermined intervals in the hollow of the protection tube body to form unit spaces and through which the power line passes; A sensor unit that measures temperature and humidity in the unit spaces; a ventilation unit connected to the unit spaces and supplying and exhausting outdoor air to the unit spaces; a temperature module unit that controls the temperature inside the unit spaces; and a control unit that controls the operation of the temperature module unit so that the measured temperature reaches a preset reference temperature, and controls the operation of the ventilation unit so that the measured humidity reaches a preset reference humidity.

Here, the unit support members are,

It is made of a heat-resistant material, and a through hole is formed through which the power line passes and is supported,

A ring-shaped fixing member having heat resistance and elasticity is formed on the inner circumference of the through hole to secure the outer circumference of the power line,

The inner periphery of the fixing member is coupled to the power line in a concavo-convex shape,

The temperature module unit,

It includes a cooling coil and a heating coil buried inside the unit support member,

The cooling coil receives current from the first current provider and is cooled to a certain cooling temperature,

The heating coil receives current from a second current provider and is heated to a certain heating temperature,

It is preferable that the first and second current providers are driven under the control of the control unit.

And first fixing rings are installed around the corrugated pipe, respectively,

First holes are formed in the first fixing rings,

Second fixing rings are installed around the unit protection tubes,

Second holes are formed in the second fixing rings,

Winders for winding or unwinding the wire are installed around one end of the protective tube body,

Wire fixing ends are formed around the other end of the protective tube body,

The wire of each of the winders passes through the first and second fixing holes and is connected to the wire fixing ends,

Each of the fixtures is rotatably installed at the wire fixing ends,

The ends of the wires are connected to each of the fixtures,

A shock sensor is installed in the protective tube body to measure the shock value and transmit it to the control unit,

Preferably, when the measured impact value reaches a preset reference impact force or higher, the control unit uses the winders to unwind the winder so that it stretches a certain length.

Additionally, around the protective tube body,

A flexible cover surrounding the winders and the wires is further provided,

It is preferable that elastic wires having elasticity are embedded in a lattice shape inside the cover.

In particular, the protective tube body,

A fire extinguishing material supply device that supplies fire extinguishing materials,

Extinguishing material supply pipes connected to each of the unit spaces to supply the extinguishing material to the unit space,

Extinguishing material discharge pipes connected to each of the unit spaces and discharging the supplied fire extinguishing material to the fire extinguishing material supplier;

A discharge pump installed on the fire extinguishing material discharge pipe to discharge the extinguishing material,

A cooler installed on the fire extinguishing material discharge pipe and cooling the discharged fire extinguishing material to a certain standard cooling temperature;

It is installed on the fire extinguishing material discharge pipe and includes filters that filter out foreign substances contained in the discharged fire extinguishing material,

The control unit,

When the temperature measured in the unit spaces reaches a preset fire temperature that causes a fire, the fire extinguishing material is supplied using the fire extinguishing material supply to the unit space that reaches the preset fire temperature, and the measured temperature reaches the preset temperature. When the fire temperature falls below, the extinguishing agent is discharged using the discharge pump.

Additionally, auxiliary fire extinguishing agent layers filled with a certain amount of powdered fire extinguishing material are formed on the inner circumference of the protective tube body at positions corresponding to the unit spaces. When the temperature inside the unit spaces rises above a certain level, the interior of the auxiliary fire extinguishing agent layers expands, and fine jets formed in the auxiliary fire extinguishing agent layers open to spray the auxiliary fire extinguishing agent.

In addition, the protective tube body portion corresponding to each of the unit spaces is further provided with imagers that acquire images of power lines disposed inside each of the unit spaces and transmit the images to the control unit.

Additionally, the outer circumferences of the unit support members are fitted into each of the fitting grooves formed on the inner circumference of the protective tube body portion.

A heat-resistant elastic layer is interposed between the fitting groove and the outer circumference of the unit support member.

Additionally, multi-stage extension bars are installed at the lower ends of the unit protection tubes, respectively. Each of the multi-stage extension bars is elastically supported by springs and operates elastically in multiple stages.

The multi-stage extension bars are fastened to the top of a support plate that is fixedly installed in the ground. The support plate is ' 'The shape forms a cross-section. Both ends of the support plate may have a shape that is spread apart from each other along the outside.

Through the above tasks, the present invention prevents damage from external shocks such as earthquakes, stably fixes power lines, forms unit sections that are divided from each other, maintains a constant posture of the protection tube for each unit section, and maintains a constant posture of the protection pipe for each unit section. It has the effect of maintaining a stable state of the power line by controlling the temperature and humidity of the power line in real time for each field.

In addition, the present invention has the effect of preventing the occurrence of fire by immediately supplying extinguishing materials when the power line rises to an abnormal temperature for each unit section or space, and recovering and reusing the extinguishing materials when the temperature exceeds the ideal temperature.

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 configuration of the underground power line protection pipe structure in the complex of the present invention.
Figure 2 is a diagram showing one unit space.
Figure 3 is a diagram showing the arrangement of the unit support member and the arrangement of the temperature module unit according to the present invention.
Figure 4 is a diagram showing an example in which a winder is installed on the body of the protection tube.
Figure 5 is a diagram showing an example in which a fire extinguishing material supply device is provided in the protection tube body according to the present invention.
Figure 6 is a diagram showing an example in which auxiliary fire extinguishing agent layers are formed on the inner circumference of the protection tube body.
Figure 7 is a diagram showing an example of a configuration in which unit protection pipes are elastically supported on a support plate by multi-stage extension bars.

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 technologies 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.

Referring to the accompanying drawings below, an underground power line protection pipe structure within the complex of the present invention is provided.

Figure 1 is a diagram showing the configuration of the underground power line protection pipe structure in the complex of the present invention. Figure 2 is a diagram showing one unit space.

Referring to Figures 1 and 2, the underground power line protection pipe structure in the complex of the present invention forms a hollow inside which the power line is placed, and has unit protection pipes 110 connected to corrugated pipes 120 at regular intervals. A protective tube body 100, unit support members 200 installed at predetermined intervals in the hollow of the protective tube body 100 to form unit spaces, and through which the power line passes, and the unit spaces. A sensor unit 50 that measures the temperature and humidity in the unit space, a ventilation unit 300 that is connected to the unit spaces and supplies and exhausts outdoor air to the unit spaces, and controls the temperature inside the unit spaces. controlling the operation of the temperature module unit 400 so that the measured temperature reaches a preset reference temperature, and driving the ventilation unit so that the measured humidity reaches a preset reference humidity. It includes a control unit 500 that controls.

The ventilation unit 300 has a fan 310 that supplies outside air, outside air supply lines 320, outside air discharge lines 330, and an exhaust pump 340.

Outdoor air supply lines 320 are connected to each unit space. First valves 321 that are opened and closed under the control of the control unit 500 are installed in each of the outdoor air supply lines 320.

Second valves 331 that are opened and closed under control of the control unit 500 are disposed in each of the outdoor air discharge lines 330.

The control unit 500 opens the first valve 321 connected to the unit space and drives the fan 310 to introduce outside air into the unit space, and discharges air from the outside air discharge line 330 connected to the unit space. The unit space can be ventilated by opening the second valve 331 and driving the exhaust pump. Accordingly, the humidity and temperature of the unit space can be varied.

The sensor unit 50 includes a temperature sensor 51 that measures the temperature in the unit space and transmits it to the control unit 500, and a humidity sensor 52 that measures the humidity in the unit space and transmits it to the control unit 500. Includes.

The underground power line protection pipe structure within the complex of the present invention provides the following effects.

The temperature and humidity of the power line can be maintained uniformly. The protection pipe body 100 is composed of unit protection pipes 110, and corrugated pipes 120 are connected between the unit protection pipes 110. The corrugated pipes 120 can adjust the size of unit spaces by adjusting the spacing between the unit protection pipes 110. Accordingly, the control unit 500 can maintain the temperature and humidity of the unit spaces uniformly by adjusting the ventilation amount by adjusting the size of the unit spaces.

Deterioration of power lines can be prevented. Power lines generate heat as current flows. This heat can damage the insulation of power lines, causing electrical accidents. The structure of the present invention can prevent deterioration of power lines by maintaining uniform temperatures in unit spaces.

The durability of power lines can be improved. Power lines can corrode or deform under the influence of the external environment. The structure of the present invention can prevent corrosion and deformation of power lines and improve durability by maintaining uniform humidity in unit spaces.

Maintenance and management can be facilitated. Since the unit protection pipes 110 are independently constructed, even if a single component fails or is damaged, the other unit protection pipes 110 are not affected. Therefore, maintenance and management are easy.

Figure 3 is a diagram showing the arrangement of the unit support member and the arrangement of the temperature module unit according to the present invention.

Referring to FIG. 3, the unit support members 200 are made of a heat-resistant material and have a through hole 210 through which the power line 10 passes and is supported.

A ring-shaped fixing member 220 having heat resistance and elasticity is formed on the inner periphery of the through hole 210 to fix the outer periphery of the power line 10.

The inner circumference of the fixing member 220 is coupled to the power line 10 in a concavo-convex shape.

The temperature module unit 400 includes a cooling coil 410 and a heating coil 420 embedded within the unit support member 200.

The cooling coil 410 receives current from the first current provider 411 and is cooled to a certain cooling temperature.

The heating coil 420 receives current from the second current provider 421 and is heated to a certain heating temperature.

The first and second current providers 411 and 421 are driven under the control of the control unit 500.

Through this configuration, the present invention provides the following effects.

The precision of temperature control of power lines can be improved. By directly controlling the temperature of the power line 10 through the cooling coil 410 and the heating coil 420, the precision of temperature control can be improved.

Deterioration of power lines can be prevented more effectively. Deterioration can be prevented by lowering the temperature of the power line 10 through the cooling coil 410, and deterioration can be prevented by increasing the temperature of the power line 10 through the heating coil 420.

The durability of power lines can be further improved. Corrosion can be prevented by lowering the temperature of the power line 10 through the cooling coil 410, and deformation can be prevented by increasing the temperature of the power line 10 through the heating coil 420.

Figure 4 is a diagram showing an example in which a winder is installed on the body of the protection tube.

Referring to Figure 4, first fixing rings 121 are installed around the corrugated pipe 120, respectively.

First holes 121a are formed in the first fixing rings 121.

Second fixing rings 111 are installed around the unit protection pipes 110.

Second holes 111a are formed in the second fixing rings 111.

Winders 510 for winding or unwinding the wire 511 are installed around one end of the protective tube body 100.

Wire fixing ends 101 are formed around the other end of the protective tube body 100.

The wires of each of the winders 510 pass through the first and second fixing holes 121 and 111 and are connected to the wire fixing ends 101.

Each of the fixtures 102 is rotatably installed at the wire fixing ends 101.

The ends of the wires 151 are connected to each of the fixtures 102.

An impact sensor 520 is installed in the protective tube body 100 to measure the impact value and transmit it to the control unit 500.

When the measured impact value exceeds a preset reference impact force, the control unit 500 may use the winders 510 to unwind the wire 511 to a certain length.

Additionally, a flexible cover 512 surrounding the winders 510 and the wires 511 is further provided around the protective tube body 100.

Inside the cover 512, elastic wires (not shown) having elasticity are buried in a lattice shape.

Referring to Figure 4, winders 510 are installed in the protection tube body 100 according to the present invention. The winders 510 can wind or unwind the wire 511, and the wire 511 serves to connect the corrugated pipes 120 and the unit protection pipes 110.

By installing the winders 510, the following effects are provided.

It can protect power lines from earthquakes or external shocks. When an earthquake or external shock occurs, the wire 511 can be unwound to a certain length using the winders 510. When the wire 511 is stretched, a certain gap is created between the power line, the corrugated pipes 120, and the unit protection pipes 110. This can prevent power lines from being damaged by earthquakes or external shocks.

The lifespan of power lines can be extended. When the wire 511 is unwound to a certain length using the winders 510, a certain gap is created between the power line, the corrugated pipes 120, and the unit protection pipes 110. This makes it easier for heat from the power line to be released to the outside, preventing deterioration of the power line.

Maintenance and management of power lines can be facilitated. By stretching the wire 511 using the winders 510, the power line can be easily separated and assembled. This makes maintenance and management of power lines easier.

Figure 5 is a diagram showing an example in which a fire extinguishing material supply device is provided in the protection tube body according to the present invention.

Referring to FIG. 5, the protection tube body 100 includes an extinguishing agent supply device 610 that supplies an extinguishing agent, and extinguishing agent supply pipes that are connected to each of the unit spaces and supply the extinguishing agent to the unit space. (620), fire extinguishing material discharge pipes 630 connected to each of the unit spaces and discharging the supplied fire extinguishing material to the fire extinguishing material supplier 610, and installed on the fire extinguishing material discharge pipe 630 to extinguish fire. A discharge pump 640 for discharging material, a cooler 650 installed on the fire extinguishing material discharge pipe 630 and cooling the discharged fire extinguishing material to a certain standard cooling temperature, and a cooler 650 on the fire extinguishing material discharge pipe 630. It is installed in and includes filters 660 that filter foreign substances contained in the extinguishing material discharged.

When the temperature measured in the unit spaces reaches a preset fire temperature that causes a fire, the control unit 500 uses the extinguishing material supply device 610 to deliver the extinguishing material to the unit space that has reached the preset fire temperature. When supplied and the measured temperature falls below the preset fire temperature, the extinguishing material is discharged using the discharge pump 640.

Referring to FIG. 5, the protection tube body 100 according to the present invention is provided with an extinguishing material supply device 610. The extinguishing material supply device 610 serves to supply the extinguishing material. The extinguishing agent supply device 610 can use various types of extinguishing agents. For example, water, fire extinguisher gas, halide gas, carbon dioxide, liquid nitrogen, liquid argon, liquid mineral oil, etc. can be used.

By installing a fire extinguishing agent supply device, the following effects are provided.

In the event of a fire, fire extinguishing agents can be quickly supplied to extinguish the fire. The extinguishing material supply device 610 can supply the extinguishing material through the extinguishing material supply pipes 620 connected to each of the unit spaces. Therefore, in the event of a fire, the fire can be extinguished by quickly supplying extinguishing substances.

Damage to power lines can be prevented. If a fire occurs, power lines may be damaged due to the heat of the fire. If extinguishing materials are supplied through the fire extinguishing material supply device 610, the heat of the fire can be cooled and damage to the power line can be prevented.

The lifespan of power lines can be extended. In the event of a fire, the insulation of the power line may be damaged due to the heat of the fire. When extinguishing materials are supplied through the fire extinguishing material supply device 610, the heat of the fire can be cooled and damage to the insulator of the power line can be prevented.

Figure 6 is a diagram showing an example in which auxiliary fire extinguishing agent layers are formed on the inner circumference of the protection tube body.

Referring to FIG. 6, auxiliary fire extinguishing agent layers 160 filled with a certain amount of powdered fire extinguishing material are formed on the inner circumference of the protective tube body 100 at positions corresponding to the unit spaces. When the temperature inside the unit spaces rises above a certain level, the interior of the auxiliary fire extinguishing agent layers 160 expands, and the fine jets (not shown) formed in the auxiliary fire extinguishing agent layers 160 open, causing the auxiliary fire extinguishing agent to be released. is sprayed.

In addition, in the protective tube body portion 100 at a position corresponding to each of the unit spaces, an image of the power line 10 disposed inside each of the unit spaces is acquired and transmitted to the control unit 500. Devices 700 are further provided. The control unit 500 compares the image transmitted to the management server 800 with the transmitted image and the preset normal image, determines that an abnormality has occurred if it is different, and sends the location information of the corresponding unit space to the server ( 800).

In addition, although not shown in the drawing, the outer periphery of the unit support members 200 is fitted into each of the fitting grooves formed on the inner periphery of the protective tube body portion 100.

A heat-resistant elastic layer is interposed between the fitting groove and the outer circumference of the unit support member.

Referring to Figure 6, auxiliary fire extinguishing agent layers 160 are formed on the inner periphery of the protection tube body 100 according to the present invention. The auxiliary fire extinguishing agent layers 160 are filled with powdered fire extinguishing material, and when the temperature inside the unit spaces rises above a certain level, the interior expands and the auxiliary fire extinguishing agent is sprayed.

By installing the auxiliary fire extinguishing agent layers 160, the following effects are provided.

In the event of a fire, the fire can be extinguished by spraying the extinguishing agent through the auxiliary extinguishing agent layers 160 before the extinguishing agent supply device 610 operates. Therefore, when a fire occurs, the fire can be quickly extinguished even if the operation of the extinguishing agent supply device 610 is delayed.

It is possible to prevent waste of fire extinguishing material due to the operation of the fire extinguishing material supply device 610. Since the fire can be extinguished by spraying the extinguishing agent through the auxiliary extinguishing agent layers 160, waste of the extinguishing agent can be prevented when the operation of the extinguishing agent supply device 610 is not required.

Damage to power lines can be prevented. When a fire is extinguished by spraying a fire extinguishing agent through the auxiliary fire extinguishing agent layers 160, damage to the power line due to the heat of the fire can be prevented.

Figure 7 is a diagram showing an example of a configuration in which unit protection pipes are elastically supported on a support plate by multi-stage extension bars.

Referring to FIG. 7, multi-stage extension bars 115 are installed at the lower ends of the unit protection pipes 110, respectively. Each of the multi-stage extension bars 115 is elastically supported by springs and operates elastically in multiple stages.

The multi-stage extension bars 115 are fastened to the top of the support plate 190 that is fixedly installed in the ground. The support plate 190 is ' 'It forms a cross section of the shape. Both ends of the support plate 190 may have a shape that is spread apart from each other along the outside.

Here, the multi-stage extension bar 115 is surrounded by a flexible protective cover 116, and the protective cover 116 is connected between the unit protective tube 110 and the support plate 190.

Referring to Figure 7, the unit protection pipes 110 according to the present invention are elastically supported on the support plate 190 by multi-stage extension bars 115.

Through this configuration, the following effects are provided.

It can effectively protect power lines from earthquakes or external shocks. When an earthquake or external shock occurs, the unit protection pipes 110 are elastically supported by the multi-stage extension bars 115, thereby preventing the power line from being damaged by the earthquake or external shock.

The lifespan of power lines can be extended. Since power lines are not damaged by earthquakes or external shocks, the lifespan of power lines can be extended.

Maintenance and management of power lines can be facilitated. Since the unit protection pipes 110 are elastically supported, the power line can be easily separated and assembled. This makes maintenance and management of power lines easier.

According to the overall configuration and operation above, the present invention prevents damage from external shocks such as earthquakes, stably fixes power lines, forms unit sections divided from each other, and maintains the posture of the protection tube for each unit section consistently. In addition, the temperature and humidity of the power line can be controlled in real time for each unit section to maintain a safe power line.

In addition, the present invention can prevent fires by immediately supplying extinguishing materials when the power line rises to an abnormal temperature for each unit section or space, and can recover and reuse the extinguishing materials when the temperature exceeds the ideal temperature.

The objects of the present invention are not limited to the objects mentioned above, and other objects and advantages of the present invention that are not mentioned can be understood by 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.

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.

10: power line
100: protection tube body
110: unit protection tube
120: Corrugated pipe
200: unit support member
210: Through hole
300: ventilation unit
400: Temperature module part
410: cooling coil
420: Heating coil
500: Control unit

Claims (4)

A protective pipe body portion that forms a hollow space inside which a power line is placed and has unit protective pipes connected to corrugated pipes at regular intervals;
unit support members installed at predetermined intervals in the hollow of the protective tube body to form unit spaces through which the power line passes;
A sensor unit that measures temperature and humidity in the unit spaces;
a ventilation unit connected to the unit spaces and supplying and exhausting outdoor air to the unit spaces;
a temperature module unit that controls the temperature inside the unit spaces; and,
A control unit that controls the operation of the temperature module unit so that the measured temperature reaches a preset reference temperature, and controls the operation of the ventilation unit so that the measured humidity reaches a preset reference humidity,
The unit support members are,
It is made of a heat-resistant material, and a through hole is formed through which the power line passes and is supported,
A ring-shaped fixing member having heat resistance and elasticity is formed on the inner circumference of the through hole to secure the outer circumference of the power line,
The inner periphery of the fixing member is coupled to the power line in a concavo-convex shape,
The temperature module unit,
It includes a cooling coil and a heating coil buried inside the unit support member,
The cooling coil receives current from the first current provider and is cooled to a certain cooling temperature,
The heating coil receives current from a second current provider and is heated to a certain heating temperature,
The first and second current providers are driven under the control of the control unit,
First fixing rings are installed around the corrugated pipe, respectively,
First holes are formed in the first fixing rings,
Second fixing rings are installed around the unit protection tubes,
Second holes are formed in the second fixing rings,
Winders for winding or unwinding the wire are installed around one end of the protective tube body,
Wire fixing ends are formed around the other end of the protective tube body,
The wire of each of the winders passes through the first and second fixing holes and is connected to the wire fixing ends,
Each of the fixtures is rotatably installed at the wire fixing ends,
The ends of the wires are connected to each of the fixtures,
A shock sensor is installed in the protective tube body to measure the shock value and transmit it to the control unit,
The control unit uses the winders to unwind the winder so that it stretches a certain length when the measured impact value reaches a preset standard impact force or more.
Underground power line protection pipe structure within the complex. delete delete According to clause 1,
Around the protective tube body,
A flexible cover surrounding the winders and the wires is further provided,
Characterized in that, inside the cover, elastic wires having elasticity are buried in a lattice shape.
Underground power line protection pipe structure within the complex.