KR101361584B1 - Smart control distributing board comprising total heat exchanger - Google Patents

Abstract

The present invention relates to smart control switchgear of a heat exchange type comprising a body frame, a temperature sensor, a humidity sensor, a dust sensor, a heat exchanger, and a vent. The body frame comprises a high-voltage device. The temperature sensor is installed inside the body frame and measures temperature. The humidity sensor is installed inside the body frame and measures humidity. The dust sensor is installed inside the body frame and measures fine dust. The heat exchanger is connected to the temperature sensor, the humidity sensor, and the dust sensor. The heat exchanger is operated according to the measured temperature, the humidity, and the fine sensor. The vent is connected to the temperature sensor, the humidity sensor, and the dust sensor. The vent is operated according to the measured temperature, the humidity, and the fine dust. The present invention is provided to control the temperature of the switchgear by using the heat exchanger, thereby improving the cooling efficiency of the switchgear.

Description

Smart control switchgear with heat exchange method {SMART CONTROL DISTRIBUTING BOARD COMPRISING TOTAL HEAT EXCHANGER}

The present invention relates to a switchgear, and more particularly to a smart control switchgear of the heat exchange method.

Generally, domestic authorized voltage such as 22.9KV, 6.6KV, 3.3KV, 440V, 380 / 220V etc. is constantly applied to transformer, breaker, and condenser inside the switchgear. In addition, the temperature rises by 10 ~ 30 ° C compared to the ambient temperature, such as heat generated by no load loss or load loss, heat generated by SOHO when the breaker is operated, heat generated by charge accumulation such as a capacitor, and heat generated by the intrinsic resistance when the electric device is operated.

Such a switchboard provides an internal space, and a control panel is provided on the front surface thereof. A plurality of busbars are provided inside the switchgear. The bus bar is a strip-shaped conductor made of copper or aluminum. A plurality of bus bars are fastened with bolts or the like as needed to provide a path for passing current.

By the way, the temperature of the internal space of such a switchboard rises to a high temperature by the resistance heat generated in the bus bar and other structures.

Such heat can not only damage the switchboard but also lead to a fire. Therefore, it is very important to precisely measure and recognize the heat state of the switchboard to prevent large accidents in advance.

On the other hand, the sealed switchgear generally uses an exhaust fan to release heat to the outside. That is, without the heat exchanger, the exhaust panel is cooled by circulating the steel in the heat distribution panel and releasing it to the outside using an exhaust fan. However, the cooling method using the exhaust fan has a limitation in cooling the switchgear that generates high temperature heat.

In addition, a switchgear that supplies a large amount of electricity in an industrial site has a very high frequency of electric component damage and fire occurrence due to heat generation, and in this case, a large loss due to an operation stoppage or a fire of a production facility may occur. Remote monitoring of such switchboards is essential.

The present invention has been proposed to solve the above problems, and an object thereof is to provide a heat exchange type smart control switchgear using a heat exchanger, for example, a heat exchanger of a total heat exchange method.

Another object of the present invention is to provide a heat exchange type smart control switchgear capable of measuring the temperature, humidity, dust inside the switchgear and control the switchgear smartly accordingly.

Still another object of the present invention is to provide a heat exchange type smart control switchgear with easy control and remote monitoring.

Smart control switchgear of the heat exchange method according to the present invention for achieving the above object, the body frame having a high-pressure device flowing electricity; A temperature sensor installed inside the body frame to measure temperature; A humidity sensor installed inside the body frame to measure humidity; A dust sensor installed inside the body frame to measure fine dust; A heat exchanger connected to the temperature sensor, the humidity sensor, and the dust sensor and driven according to the measured temperature, humidity, and fine dust; And a fan connected to the temperature sensor, the humidity sensor, and the dust sensor and driven according to the measured temperature, humidity, and fine dust.

The heat exchanger of the smart control switchgear of the heat exchange method according to the present invention is characterized in that the heat exchanger of the total heat exchange method, is operated in the rainy season, the fan is operated in the dry season.

In addition, the heat exchanger of the smart control switchgear of the heat exchange system according to the present invention is installed on the ceiling of the switchgear when the switchgear is installed indoors, and is installed on the upper front of the switchgear when the switchgear is installed outdoors. There is this.

And the smart control switchgear of the heat exchange method according to the present invention, the display unit for displaying the measured temperature, humidity, fine dust information and driving information of the heat exchanger; The control unit may be configured to operate the heat exchanger according to the rainy season or the dry season using the information, and to perform remote control of the heat exchanger.

The present invention has the effect that the cooling efficiency of the switchgear can be improved by controlling the temperature of the switchgear using a heat exchanger of a heat exchange method that has not been used in the prior art.

And by measuring the temperature, humidity, dust inside the switchgear it can control the switchgear smartly. In particular, by setting the temperature, humidity, dust, which are different standards according to the surrounding environment where the switchboard is installed, that is, a dry environment (dry season) or a humid environment (rainy season), the heat exchanger can be operated smartly according to the environment. It works. That is, in the rainy season, the heat exchanger is operated, and in the dry season, the heat exchanger is not necessary, so the fan can be operated. Thus, since the heat exchanger can be operated in accordance with the environment, there is also an effect of saving the power.

In addition, when the switchgear is installed indoors, the heat exchanger is installed on the ceiling of the switchgear, and when installed outdoors, the heat exchanger is installed on the upper front surface of the switchgear, thereby effectively solving the generation of water vapor convection in the switchgear.

The display unit provided in the switchgear facilitates control of the switchgear, for example, temperature control, and also enables remote monitoring of the switchgear. That is, it is possible to transmit and receive the temperature, humidity, and dust information remotely detected by the user's mobile phone or PC. Further, by using the received temperature, humidity, dust information, etc., it may be possible to control the power of the switchgear on / off through the user's mobile phone or PC.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

1 is a view showing a smart control switchgear of the heat exchange method according to the present invention.
2 is a block diagram schematically showing a smart control switchgear of the heat exchange method according to the present invention.
3 is a flow chart briefly illustrating a control method of a smart control switchgear of a heat exchange method according to the present invention.

Hereinafter, the smart control switchgear of the heat exchange method according to the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a view showing a smart control switchgear of the heat exchange method according to the present invention, Figure 2 is a block diagram briefly showing a smart control switchgear of the heat exchange method according to the present invention.

1 and 2, the smart control switchgear 100 of the heat exchange method according to the present invention includes a body frame 10, a temperature sensor 20, a humidity sensor 30, and a dust sensor 40. , A heat exchanger 50, a fan (not shown), a display unit 60, and a controller 70.

The body frame 10 is an outer circumference of the switchboard 100 and includes a high pressure device through which electricity flows. Body frame 10 is made of a steel plate, and contains a control unit, busbars and other necessary electrical components. The display unit 60 may be provided on the front of the body frame 10. The information of the temperature sensor 20, the humidity sensor 30, and the dust sensor 40 described below through the display unit 60 may be displayed, for example, temperature, humidity, and dust information. The display unit 60 may further include a control panel to control the operation of the temperature sensor 20, the humidity sensor 30, the dust sensor 40, and the heat exchanger 50.

The temperature sensor 20 is installed inside the body frame 10 to measure the internal temperature of the water distribution panel 100. As the temperature sensor 20, various temperature sensors such as a contact type or a non-contact type may be applied. The temperature information measured by the temperature sensor 20 is provided to the controller 70 to be described below, through which the heat exchanger 50 may be operated. The temperature information measured by the temperature sensor 20 may be provided in real time, and the temperature information may be displayed on the display unit 60.

The humidity sensor 30 is installed inside the body frame 10 to measure the internal humidity of the switchboard 100. As the humidity sensor 30, various humidity sensors such as a condensation sensor and a dew point sensor may be applied. The humidity information measured by the humidity sensor 30 is provided to the control unit 70 to be described below, through which the heat exchanger 50 may operate. The humidity information measured by the humidity sensor 30 may be provided in real time, and the humidity information may be displayed on the display unit 60.

The dust sensor 40 is installed inside the body frame 10 to measure the internal dust of the switchboard 100. The dust sensor 40 is a device for detecting the number of floating fine dust or condensed tube. When the light shines on the particles, the scattered light pattern is changed according to the size of the particles. Done. The dust information measured by the dust sensor 40 is provided to the control unit 70 to be described below, through which the heat exchanger 50 can be operated. The dust information measured by the dust sensor 40 may be provided in real time, and the dust information may be displayed on the display unit 60.

The heat exchanger 50 is connected to the temperature sensor 20, the humidity sensor 30, and the dust sensor 40 described above, and is driven according to the measured temperature, humidity, and fine dust. That is, the heat exchanger 50 may be applied to the dust sensor 40 when the temperature measured by the temperature sensor 20 is higher than the set temperature, or when the humidity measured by the humidity sensor 30 is higher than the set humidity. Can be driven if the dust measured is higher than the set dust. Here, the heat exchanger 50 is used a heat exchange method, the heat exchange method is a method of exchanging both sensible and latent heat during ventilation. That is, heat exchange is performed by moving water vapor of the air inside the switchboard 100 toward the outside air.

The heat exchanger 50 may be operated in the rainy season. That is, the heat exchanger 50 is operated when the environment in which the water distribution panel 100 is installed is a humid environment. Recognition of such an environment and the operation of the heat exchanger 50 are controlled by the controller 70 to be described below. And the heat exchanger 50 is installed on the top of the switchboard 100, in particular, when the switchboard 100 is installed indoors, is installed on the ceiling of the switchboard 100, the switchboard 100 is installed outdoors, It is installed on the upper front of the switchboard (100). By installing the heat exchanger 100 on the top of the switchgear 100, it is possible to effectively solve the generation of water vapor that is convection up inside the switchgear 100. Here, when the heat exchanger 50 is installed outdoors, the reason why the heat exchanger 50 is installed on the upper front surface of the switchboard 100 is that the heat exchanger 50 may be wet by rain or the like.

Like the heat exchanger 50, the fan is connected to the above-described temperature sensor 20, humidity sensor 30, and the dust sensor 40, and is driven according to the measured temperature, humidity, fine dust. For example, the fan may be operated in the dry season. That is, in the case of the switchgear 100 which is driven in a dry environment, since the operation of the heat exchanger 50 is not necessary, it is possible to effectively remove dust and the like inside the switchgear 100 through the fan.

The display unit 60 may be provided at the front of the switchboard 100. The display unit 60 displays temperature measured by the temperature sensor 20, humidity measured by the humidity sensor 30, fine dust information measured by the dust sensor 40, and driving information of the heat exchanger 50. Display. For this reason, the operator can easily grasp the state of the switchgear 100 can prevent a large accident in advance.

The controller 70 operates the heat exchanger 50 using temperature information by the temperature sensor 20, humidity information by the humidity sensor 30, and dust information by the dust sensor 40. That is, the controller 70 operates the heat exchanger 50 when the measured temperature is higher than the set temperature, or when the measured humidity is higher than the set humidity, or when the measured dust is higher than the set dust. Here, the control unit 70 sets the reference temperature, humidity, dust according to the surrounding environment, that is, whether the switchboard 100 is installed, that is, dry environment (dry season), humid environment (rainy season), smart according to the environment To allow the heat exchanger 50 to operate.

The control unit 70 also enables remote control of the heat exchanger 50. That is, the controller 70 can transmit and receive temperature, humidity, and dust information detected by the user's mobile phone or PC remotely via wireless or wired. Therefore, remote monitoring of the switchboard 100 is possible. Further, by using the received temperature, humidity, dust information, etc., it may be possible to control the power of the switchgear on / off through the user's mobile phone or PC.

Hereinafter, a control method of the smart control switchgear 100 of the heat exchange method according to the present embodiment will be described. 3 is a flow chart briefly illustrating a control method of a smart control switchgear of a heat exchange method according to the present invention.

Referring to FIG. 3, first, the temperature sensor 20 measures the internal temperature of the switchboard 100 (S1), the humidity sensor 30 measures the internal humidity of the switchboard 100 (S2), and the dust sensor 40. ) Measures the dust inside the switchboard (100) (S3).

After the temperature measurement in the process S1, check whether the measured temperature is above the set temperature (S4), or otherwise, the internal temperature of the switchgear 100 is measured (S1). When the temperature is higher than the set temperature in step S4, the heat exchanger 50 is operated (S7). Here, the set temperature can be changed according to the installation environment of the switchgear 100. On the other hand, when the switchboard 100 is in a dry environment, it is possible to operate the fan instead of the heat exchanger (50).

After the humidity measurement in the process S2, check whether the measured humidity is more than the set humidity (S5), or otherwise, the internal humidity of the switchboard 100 is measured (S2). When the humidity is greater than or equal to the set in step S5, the heat exchanger 50 is operated (S7). Here, the set humidity can be changed according to the installation environment of the switchgear 100.

After the dust measurement in the process S3, check whether the measured dust is more than the set dust (S6), or otherwise, the internal switchboard 100 measures the dust (S3). If more than the dust set in step S6, the heat exchanger 50 is operated (S7). Here, the set dust can be changed according to the installation environment of the switchboard (100).

Subsequently, when the operation of the heat exchanger 50 elapses (S8), the temperature, humidity, and dust inside the switchboard 100 are controlled through the temperature sensor 20, the humidity sensor 30, and the dust sensor 40. Measure again (S9, S10, S11). That is, due to the operation of the heat exchanger 50, it is checked whether the temperature, humidity, dust in the water distribution panel 100 has returned to the normal value.

Next, it is checked whether it is equal to or greater than the set value (S12), and if it is equal to or larger than the set value, the process returns to the above-described S7 process and continues to operate the heat exchanger 50.

On the other hand, if it is not more than the set value in the process S12, the operation of the heat exchanger 50 is turned off (S13). Then, the process returns to the aforementioned steps S1, S2, and S3 to continuously measure the temperature, humidity, and dust in the switchboard 100.

On the other hand, the smart control switchgear of the heat exchange method according to the present embodiment is not limited to the above-described form, it can be variously modified within the scope not departing from the technical spirit of the present invention. It will be readily apparent to those skilled in the art to which the present invention pertains.

100; Heat exchange smart control switchgear
20; temperature Senser
30; Humidity sensor
40; Dust sensor
50; heat transmitter
60; Display portion
70; The control unit

Claims (4)

A body frame having a high pressure device through which electricity flows;
A temperature sensor installed inside the body frame to measure temperature;
A humidity sensor installed inside the body frame to measure humidity;
A dust sensor installed inside the body frame to measure fine dust;
A heat exchanger connected to the temperature sensor, the humidity sensor, and the dust sensor, the heat exchanger being driven according to the measured temperature, humidity, and fine dust and operating only in the rainy season; And
And a fan connected to the temperature sensor, the humidity sensor, and the dust sensor and driven according to the measured temperature, humidity, and fine dust, and operating only in the dry period. delete According to claim 1, The heat exchanger,
When the switchboard is installed indoors, it is installed on the ceiling of the switchboard,
When the switchboard is installed outdoors, the heat exchange smart control switchboard, characterized in that installed on the upper front of the switchboard. The method of claim 2,
A display unit displaying the measured temperature, humidity, fine dust information, and driving information of the heat exchanger;
The control unit for operating the heat exchanger according to the rainy season or dry season using the information, the remote control of the heat exchanger; further comprising a smart control switchgear of the heat exchange method.

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