KR20230033921A - Ventilation System of Underground Power Line Connected to a Transformer - Google Patents

Abstract

A ventilation system of an underground power distribution line duct installed to be connected to a transformer installs an apparatus for adjusting a temperature and humidity of an underground space to bury a transformer underground and jet compression air to surroundings of the transformer according to a need or temporarily expose the transformer to the outside, thereby having an effect of adjusting a temperature and humidity in the underground space in which the transformer is buried.

Description

Ventilation System of Underground Power Line Connected to a Transformer}

The present invention relates to a ventilation system for a duct of an underground distribution line connected to a transformer, and more particularly, to bury a transformer underground, to install a mechanism for controlling the temperature and humidity of an underground space, It relates to a ventilation system of an underground distribution line duct installed connected to a transformer that sprays compressed air or temporarily exposes the transformer to the outside to adjust the temperature and humidity in the underground space where the transformer is buried, and to maintain the reliability and extend the life of the transformer. .

In general, wires such as various electric lines or communication lines were commonly installed in the air using electric poles or electric poles. However, due to the problem of spoiling the urban aesthetics due to the above electric poles and aerial wires, there is a trend of replacing or constructing new distribution lines in the form of buried underground.

In general, the existing underground distribution line construction methods can be largely divided into direct burial type, duct type, and power generation type.

The direct burial type and the conduit type are similar in construction type, only differing depending on whether or not a conduit is used.

As shown in FIG. 1, in the direct burial type and the duct type, the manhole 10 used at the cable or cable duct, the intermediate connection point or the line where the line is bent is buried underground, and the transformer (T / R, 11) and the switch (S /W, 12) is installed on the ground, and the cable is pulled out to the ground only at the point where these devices are installed and connected to the device.

However, in constructing the underground distribution line as described above, the direct burial type and the duct type have a problem that goes against the purpose of the original underground distribution line due to the equipment for installing the transformer and the switch on the ground.

These direct sales and pipeline types have space problems in construction (difficulty in installation due to civil complaints in the vicinity of private land), aesthetic impairment (painting, graffiti, or advertisements are attached to the enclosure of equipment installed on the ground, so the enclosure is painted in color as an improvement measure) However, as time goes by, the appearance changes ugly, and it is mostly used as a place to collect garbage, so it looks like a huge trash can), safety hazards (dangers of pedestrians due to heat or explosion generated by the device, and There are many problems such as the risk of electric shock in rainy weather, lack of oxygen inside the manhole and the risk of suffocation when working in the manhole due to harmful gas), and the risk of collision (collision with vehicles or pedestrians).

Despite these various problems, burying the transformer underground is a problem in that perfect waterproof construction is not performed and heat generated from the device must be released, so the device (transformer, switchgear) cannot be buried underground. There is no situation.

Accordingly, a method of slimming or miniaturizing the equipment is also sought, and the equipment is installed in the outskirts, inside the building or on the roof (requires the owner's lease approval), or a separate equipment set called a distribution station is formed, but unnecessary budget is required. Since this additional input is required and the loop of the line is bypassed, the construction is difficult and lengthy, and the maintenance of the facility continues to be difficult, so the fundamental problem has not been solved.

Republic of Korea Patent Registration No. 10-1125007 (registration date: March 02, 2012), title of invention: "Underground Buried Underground Distribution Line for Ground Underground Distribution Power Facilities by Underground Manhole Drainage and Ventilation System"

In order to solve the problems and necessities of the prior art, the present invention installs a mechanism for controlling the temperature and humidity of the underground space in order to bury the transformer underground, and sprays compressed air around the transformer or transformer as needed. The purpose is to provide a ventilation system of an underground distribution line duct connected to a transformer that controls temperature and humidity in an underground space where a transformer is buried by temporarily exposing it to the outside.

In addition, an object of the present invention is to provide a ventilation system of an underground distribution line duct connected to and installed in a transformer that maintains reliability and extends the life expectancy of the transformer buried in the ground.

The forced ventilation system 100 of the underground distribution line duct connected to the transformer of the present invention for achieving the above object,

Cable manhole 101 in which the transformer 102 is buried underground;

A first door structure 120 and a second door structure 130 having a structure in which the ceiling surface of the cable manhole 101 slides and opens and closes; and

A base body 111 formed on the rear surface of the transformer 102 to support the transformer 102 and extending upward in a rectangular parallelepiped shape, and the base body 111 is located at the center of the hollow part 111a. The first screw 115 is erected vertically, the first bevel gear 117 is coupled to the lower end of the first screw 115, and the second bevel gear ( 118) is gear-engaged, the second bevel gear 118 is coupled to the rotation shaft 119 of the drive motor 119a, and the first screw 115 is formed long in the longitudinal direction to form a predetermined shape. 1 A lift module that penetrates and couples the moving block part 115, and the first moving block part 116 extends from one side and couples the flat plate-shaped seating part 116a on which the transformer 102 is mounted ( 110).

The present invention having the above configuration facilitates the injection of compressed air or discharge of sewage in order to dissipate heat or remove moisture generated in the transformer generated when the transformer is buried underground, thereby creating an environment in which the transformer can be buried underground. There are possible effects.

On the other hand, the present invention has the effect of controlling the temperature and humidity of the underground space in order to bury the transformer underground.

In addition, the present invention has the advantage of maintaining the reliability and extending the life expectancy of the transformer buried in the ground.

1 is a diagram showing the overall schematic configuration of an underground distribution line according to the prior art,
2 and 3 are views showing the configuration of a ventilation system of an underground distribution line duct connected to and installed in a transformer according to an embodiment of the present invention,
4 is a perspective view showing the configuration of a lift module for raising and lowering a transformer according to an embodiment of the present invention;
and
5 is a diagram showing components electrically connected to a control unit according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and similar surface symbols are attached to similar parts throughout the specification.

Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated.

Transformers have many problems in terms of safety (risk of pedestrians due to heat or explosion generated by the device, risk of electric shock in rainy weather, lack of oxygen inside the manhole and risk of suffocation when working in the manhole due to harmful gas).

In order to solve this problem, if equipment such as a transformer or switchgear is buried underground, the equipment (transformer, switchgear) is buried underground because problems such as failure of the equipment or fire caused by it due to heat generated from the equipment cannot be solved. It is a situation that can not be buried.

In order to solve this problem, the present invention provides a ventilation system of an underground distribution line duct connected to a transformer.

2 and 3 are diagrams showing the configuration of a ventilation system of an underground distribution line conduit connected to and installed with a transformer according to an embodiment of the present invention, and FIG. 4 is a view of a lift module for raising and lowering a transformer according to an embodiment of the present invention. It is a perspective view showing a configuration, and FIG. 5 is a diagram showing a configuration device electrically connected to a control unit according to an embodiment of the present invention.

In the ventilation system 100 of the underground distribution line duct connected to the transformer according to the embodiment of the present invention, the transformer 102 is buried underground in the cable manhole 101, and the underground cable 103 passing through the cable manhole 101 ) has a state connected to each other on one side of the transformer 102.

The grating mount 104 serves as an installation floor for the transformer 102, and at the same time performs an excellent drainage function due to the plurality of lattice panels of the grating itself.

When rainwater flows into the vicinity of the transformer 102, the leachate and rainwater fall into the water storage space 160 at the bottom through the grating installation 104 and flow into the collecting well (not shown) through the drain pipe 161. It is discharged.

The transformer 102 is coupled to the lift module 110 and moves up and down.

The lift module 110 is formed on the rear surface of the transformer 102 to support the transformer 102 and includes a rectangular parallelepiped-shaped base body 111 extending upward.

The lift module 110 forms a bar-shaped first support 112 extending from the lower end in the left and right directions from the base body 111, and bends both ends of the first support 112 at right angles to transform the transformer. A second support 113 and a third support 114 are formed surrounding the circumference of 102.

The base body 111 forms a hollow part 111a, which is an empty space in which a vertical movement device is disposed and can rise and fall in the vertical direction.

In the base body 111, the first screw 115 is vertically erected at the center of the hollow part 111a, the first bevel gear 117 is coupled to the lower end of the first screw 115, and the first bevel gear The second bevel gear 118 is gear-engaged and engaged in the vertical direction to 117, and the second bevel gear 118 is coupled to the rotational shaft 119 of the driving motor 119a.

The first screw 115 is formed in a straight line shape with a constant length, and is formed long in the longitudinal direction so as to pass through the first moving block portion 116 .

The first screw 115 is formed long in the longitudinal direction and is coupled through the first moving block portion 115 having a predetermined shape.

The first screw 115 is processed by rolling or grinding a screw groove along the circumferential direction.

The first moving block part 116 forms a nut part (not shown) therein, and a first screw 115 is coupled through the center of the nut part.

The nut part of the first moving block part 116 forms a through hole penetrating the front and rear surfaces so that the first screw 115 is coupled to the central portion, and a screw formed on the outer circumferential surface of the first screw 115 on the inner circumferential surface of the through hole. Grooves and corresponding threads are formed.

The first screw 115 is inserted into the through hole of the nut portion of the first moving block portion 116 so that the screw groove and the screw thread are screwed together.

The first moving block part 116 extends from one side and couples the plate-shaped seating part 116a.

The seating portion 116a has a rectangular parallelepiped shape and is disposed in the space between the second support 113 and the third support 114, and mounts the transformer 102 on its upper surface.

When the first screw 115 is rotated according to the driving of the driving motor 119a, the first moving block part 116 and the seating part 116a may move up or down along the first screw 115.

In the cable manhole 101, a first side spray means and a second side spray means in the vertical direction are installed on both inner walls, and the first side spray means has a first spray nozzle 141 that sprays air at regular intervals. And, the second side injection unit is formed with a second injection nozzle 151 for injecting air at regular intervals.

The first injection nozzle 141 includes a first nozzle opening 141a inclined upward toward the end, a second nozzle opening 141b formed in a horizontal direction toward the end, and a shape inclined downward toward the end. A discharge port 141d extending from the first nozzle port 141a, the second nozzle port 141b, and the third nozzle port 141c and having a wider diameter from one side to the other side, including a third nozzle port 141c of ) to form

The second spray nozzle 151 has the same structure as the first spray nozzle 141 .

Due to this nozzle structure, the first spray nozzle 141 and the second spray nozzle 151 configure various air spray angles to spray the entire inner space of the cable manhole 101.

The first spray nozzle 141 communicates with the first spray passage 142 coupled to one surface. The second spray nozzle 151 communicates with the second spray passage 152 coupled to one surface.

The first compressed air supply unit 140 for supplying compressed air is connected to the first spray passage 142 , and the second compressed air supply unit 150 for supplying compressed air is connected to the second spray passage 152 .

The first compressed air supply unit 140 includes a first air tank 144 and a first blower 147 . The second compressed air supplier 150 includes a second air tank 154 and a second blower 157 .

The first air tank 144 includes a first air compressor (not shown) capable of compressing air to a certain pressure, and stores compressed air.

The second air tank 154 includes a second air compressor (not shown) capable of compressing air to a certain pressure, and stores compressed air.

The first air tank 144 is connected to the first spray passage 142 by a first air passage 143 through which air flows, and the second air tank 154 supplies air to the second spray passage 152. They are connected by the second air passage 153 through which they flow.

A first discharge amount control valve 145 capable of selectively supplying air on the passage is installed in the first air passage 143 .

A second discharge amount control valve 155 capable of selectively supplying air is installed in the second air passage 153.

The first and second blowers 147 and 157 include a fan (not shown) that sucks in air and a motor (not shown) that generates and provides rotational force coupled to a rotating shaft of the fan.

The inlet side of the first blower 147 is connected to the first exhaust duct 147a communicating with the outside, and the outlet side of the first blower 147 is connected to the first connection duct 146 on one side of the first air tank 144. connect with

The first blower 147 serves to supply air to the first air tank 144 through the first connection duct 146 .

The first air tank 144 supplies air to the cave manhole 101 and serves to fill the air at a constant pressure.

The first air tank 144 is connected to the water storage space 160 by a third air passage 148 through which air flows. The third air passage 148 passes through the water storage space 160, and a third discharge amount control valve 149 capable of selectively supplying air is installed on the third air passage 148.

At the end of the third air passage 148 penetrating the water storage space 160, a first nozzle 148a is formed obliquely at a predetermined angle to spray compressed air to the inner surface of the water storage space 160.

The second air tank 154 is connected to the water storage space 160 by a fourth air passage 158 through which air flows. The fourth air passage 158 passes through the water storage space 160, and a fourth discharge amount control valve 159 capable of selectively supplying air is installed on the fourth air passage 158.

At the end of the fourth air passage 158 penetrating the water storage space 160, a second nozzle 158a is formed obliquely at a predetermined angle to spray compressed air to the inner wall surface of the water storage space 160.

The shape of the first spray hole 148a and the second spray hole 158a force air to the inner wall surface of the water storage space 160 to prevent leachate, sewage, and other garbage accumulated in the water storage space 160 from descending. spray

The inlet side of the second blower 157 is connected to the second exhaust duct 157a communicating with the outside, and the outlet side of the second blower 157 is connected to the second connection duct 156 on one side of the second air tank 154. connect with

The second blower 157 serves to supply air to the second air tank 154 through the second connection duct 156.

The second air tank 154 supplies air to the cave manhole 101 and serves to fill the air at a constant pressure.

The first discharge amount control valve 145, the second discharge amount control valve 155, the third discharge amount control valve 149, and the fourth discharge amount control valve 159 are configured in the form of solenoid valves, but are not limited thereto, and air It can be configured by various means such as a pump.

The cable manhole 101 has a structure in which the ceiling surface is opened and closed by sliding, and includes a first door structure 120 and a second door structure 130.

The first door structure 120 is divided into a first upper partition wall 121 and a first lower partition wall 122 to form a constant first space portion 123 in the longitudinal direction therebetween, and the first space portion ( 123), the first rack gear 124 is disposed in the horizontal direction, and the first pinion gear 125 engaged with the first rack gear 124 is coupled to one side of the first lower bulkhead 122, , The first drive motor 126 is coupled to the rotation shaft (not shown) of the first pinion gear 125.

The first pinion gear 125 of the present invention is a configuration in which the first drive motor 126 is directly coupled to the rotating shaft, but is not limited thereto, and a gearbox (not shown) is coupled to the rotating shaft, and a gearbox is provided on one side of the gearbox. It may also be formed in a configuration in which one drive motor 126 is coupled.

As the first drive motor 126 rotates, the first pinion gear 125 rotates, and the first rack gear 124 inserts the first space 123 according to the rotation of the first pinion gear 125. and repeat the departure.

The second door structure 130 is internally divided into a second upper partition wall 131 and a second lower partition wall 132 to form a constant second space portion 133 in the longitudinal direction therebetween, and the second space portion ( 133), the second rack gear 134 is disposed in the horizontal direction, and the second pinion gear 135 engaged with the second rack gear 134 is coupled to one side of the second lower bulkhead 132, , The second drive motor 136 is coupled to the rotation shaft (not shown) of the second pinion gear 135.

The second pinion gear 135 of the present invention is a configuration in which the second drive motor 136 is directly coupled to the rotation shaft, but is not limited thereto, and a gearbox (not shown) is coupled to the rotation shaft, and a gearbox is provided on one side of the gearbox. It may also be formed in a configuration in which two driving motors 136 are coupled.

The second pinion gear 135 is rotated according to the rotation of the second drive motor 136, and the second rack gear 134 inserts the second space portion 133 according to the rotation of the second pinion gear 135. and repeat the departure.

The first rack gear 124 and the second rack gear 134 slide on both sides to open and close the ceiling surface of the cable manhole 101 .

The temperature sensor 105 is a sensor that measures the indoor temperature of the inner space of the cable manhole 101, and the humidity sensor 106 is a sensor that measures humidity information of the inner space of the cable manhole 101. One or more temperature sensors 105 and humidity sensors 106 may be installed at various locations in the inner space of the cable manhole 101.

The control unit 107 includes a temperature sensor 105, a humidity sensor 106, a display unit 108, a speaker 109, a first discharge amount control valve 145, a second discharge amount control valve 155, and a third discharge amount control It is electrically connected to the valve 149, the fourth discharge amount control valve 159, the drive motor 119a, the first drive motor 126, and the second drive motor 136.

The display unit 108 and the speaker 109 may be installed on one side of the outer circumferential surface of the transformer 102 .

The control unit 107 measures and periodically stores the temperature and humidity values from the temperature sensor 105 and the humidity sensor 106, and determines whether the temperature and humidity values are equal to or greater than a predetermined first reference value.

When the controller 107 determines that the temperature value and the humidity value are equal to or greater than the preset first reference value, the control unit 107 transmits a control valve driving signal to the first discharge amount control valve 145 and the second discharge amount control valve 155 to supply the first air. The air in the tank 144 and the second air tank 154 is controlled to be supplied to the inner space of the cable manhole 101.

The controller 107 transmits a motor driving signal to the first driving motor 126 and the second driving motor 136 when it is determined that the temperature value and the humidity value are equal to or greater than the preset second reference value. Here, the second reference value means a numerical value in a state in which the temperature value and the humidity value are higher than the first reference value.

Accordingly, the first rack gear 124 and the second rack gear 134 slide and move in directions away from each other, and the ceiling surface of the cable manhole 101 is opened.

Subsequently, the control unit 107 generates a motor driving signal and transmits it to the driving motor 119a. Then, when the first screw 115 is rotated, the first moving block part 116 and the seating part 116a rise along the first screw 115 .

The ceiling surface of the cable manhole 101 is opened, and a part of the transformer 102 may escape to the outside.

When a part of the transformer 102 is separated from the cable manhole 101, the control unit 107 controls the display unit 108 to output a warning signal preventing people from approaching as a light emitting signal, and the speaker 109 is controlled to output the danger signal as a voice signal.

Of course, as another embodiment, the ceiling surface of the cable manhole 101 may not be opened, and the transformer 102 may be moved only to the top of the cable manhole 101.

When the ceiling surface of the cable manhole 101 is opened, outside air is introduced into the inner space of the cable manhole 101 to control temperature and humidity.

The controller 107 is electrically connected to a pressure regulator (not shown) of the first air tank 144 and the second air tank 154, and controls the pressure of the first air tank 144 and the second air tank 154. The pressure value may be adjusted, or air may be supplied to the first air tank 144 and the second air tank 154 by driving the first blower 147 and the second blower 157 .

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present invention defined in the following claims are also included in the scope of the present invention. that fall within the scope of the right.

100: Forced ventilation system of the underground distribution line connected to the transformer
110: lift module 120: first door structure
130: second door structure 140: first compressed air supply unit
150: second compressed air supply unit

Claims (2)

Cable manhole 101 in which the transformer 102 is buried underground;
A first door structure 120 and a second door structure 130 having a structure in which the ceiling surface of the cable manhole 101 slides and opens and closes; and
A base body 111 formed on the rear surface of the transformer 102 to support the transformer 102 and extending upwardly in the shape of a rectangular parallelepiped, and the base body 111 is located at the center of the hollow part 111a. The first screw 115 is erected vertically, the first bevel gear 117 is coupled to the lower end of the first screw 115, and the second bevel gear ( 118) is meshed with a gear, the second bevel gear 118 is coupled to the rotating shaft 119 of the driving motor 119a, and the first screw 115 is formed long in the longitudinal direction to form a predetermined shape. 1 A lift module that penetrates and couples the moving block part 116, and the first moving block part 116 extends from one side and couples the flat plate-shaped seating part 116a on which the transformer 102 is mounted ( 110), the ventilation system of the underground distribution line duct connected to the transformer.
The method of claim 1,
The cable manhole 101 has a first side spraying means and a second side spraying means installed in the vertical direction on both inner walls, and the first side spraying means is a first spray nozzle 141 for spraying air at regular intervals. ) Is formed, and the second side injection means is installed connected to a transformer in which a second injection nozzle 151 for injecting air at regular intervals is formed.

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