KR100977764B1 - Method for installing 24 consecutive hours driving ventilator used photovoltaic for underground distribution lines - Google Patents

Abstract

PURPOSE: An installation method for a ventilator continuously driving sunlight is provided to forcefully circulate inside a housing by forcefully driving a ventilation fan using electrical energy. CONSTITUTION: An installation method for a ventilator continuously driving sunlight is as follows. The position of a housing for a solar panel, a controller, and multiple ventilation fans is marked(S1). The marked position is bored(S2). A solar panel, a controller, and multiple ventilation fans are installed in the bored position(S3). The solar panel, the controller, and the ventilation fans are arranged(S4). The controller is set(S5). A waterproofing work is performed using silicon(S6). The solar panel is installed on the outer surface of the housing. The controller and the ventilation fans are installed inside the housing.

Description

Installation method of solar continuous drive ventilation device for ground apparatus {METHOD FOR INSTALLING 24 CONSECUTIVE HOURS DRIVING VENTILATOR USED PHOTOVOLTAIC FOR UNDERGROUND DISTRIBUTION LINES}

The present invention relates to a method of installing a solar continuous drive ventilation device for ground equipment, and in particular, for ground equipment for ventilating the interior of the enclosure including the ground equipment for underground distribution lines for 24 hours by using the light energy of the sun as a drive source It is related with the installation method of a solar continuous drive ventilation apparatus.

In recent years, in urban areas, 22.9 kV-class high-voltage power cables have been buried in the ground for the purpose of improving aesthetics and preventing electrical safety accidents.

Such underground cables are connected to underground transformers or columnar transformers installed on the ground, and are supplied to customers by bringing down high voltage to commercial AC power in underground transformers or columnar transformers.

At this time, a ground device such as a switchgear to control the underground cable is installed at the place where the underground cable is drawn out to the ground, and the ground equipment is accommodated in the enclosure to protect the access of the pedestrian.

However, these enclosures drill only a few holes to ventilate the interior of the enclosure with natural ventilation.

This natural ventilation ventilation is very weak, the temperature difference between the inside and outside of the enclosure may be large.

The temperature difference inside and outside the enclosure increases the humidity inside the enclosure, and causes condensation inside the enclosure.

That is, condensation, which is a phenomenon in which the air temperature including moisture drops below the dew point and the moisture contained in the water forms water droplets on the surface of the object, is especially generated during winter or at night due to temperature or humidity differences inside and outside of the enclosure. do.

When such condensation occurs inside the enclosure, mold may occur on the surface of the ground apparatus in the enclosure, causing corrosion of the surface of the ground apparatus, causing problems such as damage, malfunction, and inoperability.

In addition, the natural ventilation ventilation has a problem that can not be cooled quickly when an overload or overheating phenomenon occurs during the operation of the ground equipment shortens the life and explosion of the device.

The present invention is to solve the above problems, by continuously forming a ventilation inside the enclosure solar continuous drive for ground equipment that can prevent the occurrence of condensation, high humidity, overheating, etc. generated inside the enclosure It aims to provide the installation method of a ventilation device.

The installation method of the solar continuous drive ventilation device for a ground apparatus of the present invention comprises the steps of marking the position of the solar panel, the controller and the housing to be installed a plurality of ventilation fans, puncturing the marked position; Installing the solar panel, the controller and the plurality of ventilation fans in a perforated position, wiring the solar panel, the controller and the plurality of ventilation fans, and the plurality of ventilation fans are independent And setting the controller to be continuously driven day and night, and waterproofing the silicon between the solar cell panel and the plurality of ventilation fans and the housing, wherein the solar cell panel is an outer surface of the housing. The controller and the plurality of ventilation fans are installed in the housing, wherein the plurality of ventilation fans It may be provided to be superimposed on the vent arrangement comprising a plurality of slits formed in the housing.

And mounting a cradle extending through the slit over the housing prior to installing the ventilation fan on the housing to the rear of the ventilation fan.

The division of day and night may be based on any one of a time preset in the controller, an amount of sunshine, and a temperature difference inside and outside the housing.

According to the installation method of the solar continuous drive ventilation device for ground equipment of the present invention, the day and night by the electric energy generated in the solar panel can be forcibly circulated air inside the housing by forcibly driving the ventilation fan alternately The dew condensation phenomenon and high humidity state by the temperature difference inside and outside a housing can be prevented.

Therefore, it is possible to prevent corrosion, malfunction, inoperability, and the like of the ground equipment and the automation equipment installed inside the housing, thereby preventing unnecessary expenses.

In addition, even when overload or overheating occurs during the operation of the ground equipment in the housing, it is possible to prevent the explosion or shortened life of the ground equipment by forced ventilation in the housing.

In addition, since the plurality of ventilation fans are independently driven alternately, damage to the ventilation fan due to continued driving can be prevented.

1 is a view showing in sequence the installation method of the solar continuous drive ventilation device for ground equipment according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing the state installed in the solar continuous drive ventilation apparatus housing for ground equipment by the method of Figure 1;
Figure 3 is a schematic view showing the wiring of the solar continuous drive ventilation device for ground equipment of FIG.

Hereinafter, the installation method of the solar continuous drive ventilation device for a ground apparatus of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the installation method of the continuous continuous solar ventilation apparatus for ground equipment according to an embodiment of the present invention, Figure 2 is a continuous continuous solar ventilation apparatus for ground equipment by the method of Figure 1 FIG. 3 is a view schematically showing the installed state, and FIG. 3 is a view schematically showing the wiring of the solar continuous drive ventilation device for the ground apparatus of FIG. 2.

1 to 3, the installation method of the solar continuous drive ventilation device for ground equipment of the present invention is a marking step (S1), a drilling step (S2), a ventilation device installation step (S3), wiring step (S4), setting step S5 and waterproofing step S6.

The marking step S1 is a step of designating and displaying a position at which the ventilation device 100 is to be installed in the housing 200 in which the ground apparatus 300 is embedded.

The drilling step (S2) is a step of forming a hole (not shown) of a predetermined size by a drilling means such as an electric drill in the marked portion of the housing 200.

The ventilation device installation step (S3) is a solar cell panel 110, a plurality of ventilation fans 130, and a battery on the inner and outer surfaces of the housing 200 through the holes formed by the drilling step (S2). It is the step of installing the controller 120 having 121).

Here, the solar cell panel 110 is installed on the outer surface of the housing 200, the position that can receive the maximum amount of sunlight in consideration of the direction of the south-facing direction, considering the shade or surrounding terrain formed by the surrounding buildings. Select and install first.

The controller 120 including the ventilation fan 130 and the battery 121 is installed on an inner surface of the housing 110.

The ventilation fan 130 is for ventilating the inside of the housing 200 by discharging the air inside the housing 110 to the outside through the ventilation holes 210 formed in a plurality of slits on the side of the housing 110. The ventilation hole 210 may be disposed to overlap.

Here, the ventilation fan 130 may be disposed overlapping with the ventilation port 210 through a cradle (not shown), specifically one side of the cradle is coupled to the rear of the ventilation fan 130, the other side The ventilation fan 130 may be disposed to be overlapped with the ventilation port 210 in such a manner as to be exposed to the outside of the housing 200 through any one of the slits forming the ventilation hole 210.

Therefore, in order to install the ventilation fan 130 on the housing 200 by using the holder, the step of mounting the holder on the ventilation fan 130 before the installation step S3 of the ventilation device is preceded.

On the other hand, by attaching a double-sided tape or silicon to the ventilation fan 130 may increase the adhesion of the ventilation fan 130.

The wiring step (S4) is a step of electrically connecting the ventilation device 100, that is, the solar cell panel 110, and the controller 120 having the ventilation fan 130 and the battery 121. to be.

That is, the solar cell panel 110, the plurality of ventilation fans 130, and the battery 121 are connected to the controller 120, respectively.

The electrical energy generated by the solar cell panel 110 by the wiring drives the ventilation fan 130 through the controller 120 or is stored in the battery 121 to receive light energy such as night time. When it is not possible to act as a driving source of the ventilation fan 130.

The setting step S5 is a step of setting the controller 120 so that each of the plurality of ventilation fans 130 is independent and alternately continues to be driven day and night.

For example, when the ventilation fan 130 is two, one is driven during the day, the other one is set to the timer function in the controller 120 to be driven at night, day and night, that is, 24 hours in the housing 200 To ventilate.

Here, day and night may be divided by time, amount of sunshine, temperature difference inside and outside the housing, and the like.

The division by time may be divided into a day and a night by setting a predetermined time, for example, a time between 6 am and 6 pm, 24 hours a day, and setting other times as night.

The daylight and daylight division is a method of setting the comparison value of the amount of electrical energy supplied from the solar cell panel 110 to the controller 120 as the sunshine amount reference value when the sunshine amount is smaller than the sunshine amount value at night, and when it is larger than the daytime. Can be distinguished.

The classification by the temperature difference between the inside and the outside of the housing 200 is set to daytime when the temperature difference between the inside of the housing 200 and the outside temperature is within a predetermined range, and is set to daytime when the temperature is outside the predetermined range. Can distinguish nighttime.

The waterproofing step (S6) is a step of waterproofing with silicon or the like on the edges of the solar cell panel 110 and the plurality of ventilation fans 130 installed in the housing 200, which is rainwater or foreign matter solar cell panel This is to prevent the flow into the 110 or the ventilation fan 130.

According to the installation method of the solar continuous drive ventilation device for ground equipment as described above, by day and night by the electric energy generated in the solar cell panel 110 is alternately forced to drive the ventilation fan 130 inside the housing 200 Since the air can be forced to circulate, condensation or high humidity can be prevented due to a temperature difference between the inside and the outside of the housing 200.

Therefore, corrosion, malfunction, or inoperability of the ground apparatus 300 or the automation apparatus installed in the housing 200 can be prevented, and unnecessary expenses can be prevented.

In addition, even when overload or overheating occurs during the operation of the ground device 300 in the housing 200, it is possible to prevent explosion or shortening of the life of the ground device 300 by forced ventilation in the housing 200.

In addition, since the plurality of ventilation fans 130 are independently driven alternately, damage to the ventilation fan 130 due to continued driving can be prevented.

In addition, since the driving source of the ventilation fan 130 by the solar cell panel 110 to produce electrical energy using light energy, there is an environmentally friendly, economical advantage.

100 ... ventilation 110 ... solar panel
120 ... Controller 121 ... Battery
130 ... ventilating fan 200 ... housing
210 ... vent 300 ... ground equipment

Claims (3)

Marking at the position of the solar panel, the housing where the controller and the plurality of ventilation fans are to be installed;
Drilling the marked position;
Installing the solar cell panel, a controller and a plurality of ventilation fans at the perforated positions;
Wiring the solar cell panel with a controller and a plurality of ventilation fans;
Setting the controller such that the plurality of ventilation fans are independent of each other and continuously driven day and night; And
Waterproofing work by the silicon between the solar panel and the plurality of ventilation fans and the housing; including,
The solar cell panel is installed on the outer surface of the housing, the controller and the plurality of ventilation fans are installed in the housing, the plurality of ventilation fans are installed so as to overlap the ventilation opening consisting of a plurality of slits formed in the housing ,
Mounting a cradle extending through the slit over the housing prior to installing the ventilation fan on the housing to the rear of the ventilation fan; Installation method of the solar continuous drive ventilation device for ground equipment further comprises a.

delete The method according to claim 1,
The day and night division is based on any one of the time set in the controller, the amount of sunshine and the temperature difference between the inside and outside of the housing installation method of the solar continuous drive ventilation device for ground equipment.

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