KR20200094446A - Prevention of shutting off the power supply and Double power supply apparatus for Inverter control board - Google Patents

Abstract

According to the present invention, an apparatus for dual power supply and overheating prevention of an inverter control board comprises: an air inlet installed on the lower end of an inverter control board; a filter installed near the air inlet; an air circulation path having a separate space to circulate air passing through the filter; an air discharge fan to discharge air passing through the air circulation path; a heat radiation plate of an inverter installed to be exposed towards the air distribution path; and an air-blowing fan installed on the upper end of the inverter control board. According to the present invention, air entering through the air inlet passes through the air circulation path via the filter and cools a large quantity of heat generated by the heat radiation plate. Also, if a dual power supply apparatus consisting of a battery and a charger connected to an alternating current power source is constructed in preparation for the case where an inverter control board communication unit for communication of an inverter control board monitoring system malfunctions by a power outage, power supplied by the battery can be used in a power outage to prevent power shutoff of the inverter control board communication unit.

Description

Prevention of overheating of the inverter control panel and double power supply apparatus{Prevention of shutting off the power supply and Double power supply apparatus for Inverter control board}

The present invention relates to a technique for preventing overheating of an inverter control panel and a dual power supply. In particular, when the inverter control panel is overheated, the operation of the inverter is stopped, the inverter is malfunctioning, and when the AC power is cut off due to a power failure, the present invention relates to a technology for protecting the power cut-off of the communication unit of the inverter control panel.

An inverter is a power conversion device for converting direct current into alternating current.

An inverter is a power converter used to use a specific power source (voltage source, current source, frequency, size, direction) as a power source for other components. In general, a power converter whose output power is AC (AC) is called an inverter.

The type of inverter is divided according to the output waveform and the drive method. There are three types: power inverters, motor inverters, and high-voltage inverters. There are two types of power inverters depending on the circuit mechanism, four types according to the programming mechanism, and two types depending on the mechanical mechanism.

Inverters for electric motors first determine whether they are for induction motors or synchronous motors, and then pick a mechanism. Inverters for synchronous motors are usually called transmissions.

A solar inverter is a device that converts a DC voltage from a solar cell (module) into an AC voltage and supplies power. It is a device that converts a DC voltage into an AC voltage of 60 Hz (domestic standard), and the capacity of the inverter is often determined according to the solar power generation capacity.

An inverter is as important as a solar module during solar power generation.

Even if the panel produces more power generation than the capacity, it cannot exceed the capacity of the inverter, and the inverter converts the DC voltage generated by the solar module into a commercial grid voltage and an AC voltage used as a load, so the inverter generates photovoltaic power. It can be said to be the core electrical equipment.

The inverter has various functions such as an automatic operation stop function, a maximum power follow-up control function, a single operation prevention function, a DC detection function, a DC ground fault detection function, an automatic voltage adjustment function, and a system connection protection function.

When the inverter, which plays such an important role, stops working due to overheating or has a malfunction, the power supply to the commercial and load is cut off, so that the energy generated from solar power cannot be used, resulting in a problem in terms of revenue generation, the purpose of the solar inverter. .

Generally, an industrial inverter (inverter for a motor) is installed inside the inverter control panel. The inverter control panel is equipped with an inverter, a main breaker, a current transformer (CT), a noise filter, an enhanced multi-point relay (EMPR), and a transformer (TR) in a rectangular rectangular cabinet. In this case, when heat is generated from a heat sink plane attached to the rear of the inverter, and the temperature of the inverter control panel inside the cabinet rises rapidly, the inverter may stop or malfunction.

In addition, there is a problem that the power supply is cut off not only in the control panel but also in the monitoring system when a power outage occurs in the AC power supplied to the inverter.

In particular, the monitoring system plays an important role in supplying various information such as the operating state of the inverter, the operating state of the control panel, and the amount of power generation to the user through a communication network, as well as the operating state of the motor controlled by the inverter.

In addition, the inverter control panel has a problem of corrosion of electronic devices built in the inverter control panel or malfunction of the inverter while dust, impurities, and salt mixed in the air introduced for heat dissipation are introduced depending on the installation environment.

Registered Patent Publication No. 10-1224993 (Announcement date: January 22, 2013) Registered Patent Publication No. 10-1253331 (Announcement date: April 4, 2013)

The problem to be solved of the present invention is to provide a protection device and a heat dissipation structure that can prevent malfunction and system stoppage due to overheating of the inverter control panel.

Another problem to be solved of the present invention is to supply power to the monitoring system by automatically supplying communication-related power through a secondary battery when power is cut off due to a power outage, so that the inverter control panel communication unit status and failure report to the user The idea is to provide a dual power supply that can be informed and promptly followed up.

Overheating prevention and dual power supply of the inverter control panel of the present invention is an inverter control panel including an inverter, a main circuit breaker, a current transformer, an overcurrent relay, a transformer, a switching element, and a monitoring device, the first being installed on the lower side of the inverter control panel An air inlet and a second air inlet, a first air intake grid and a second air intake grid installed on the side or front of the inverter control panel, and a filter installed near the inside of the first air inlet and the second air inlet. , An air circulation path having a separate space to allow air passing through the filter to circulate, and an air discharge fan through which air passing through the air circulation path heats the heat sink of the inverter and discharges air containing heat, It comprises a blower fan installed at the upper end of the inverter control panel to discharge heat generated from electronic components, an inverter control panel communication unit for communication of the monitoring device, and a first air suction grid on the side or front of the inverter control panel and The air entering the first air inlet exits the hole of the inverter control panel to cool the front part, is discharged to the blower fan through the bottom hole, and the air passing through the filter passes through the second air intake grid and the second air inlet. The air entering the rear side of the inverter passes through the heat sink of the inverter and is discharged to the air exhaust fan so that much heat generated from the heat sink of the inverter can be cooled.

The inverter control panel communication unit comprises a program control unit, a sensor, a monitoring unit, and a database, and includes a dual power supply unit configured by connecting a charger and a battery to AC power supplied to the inverter control panel communication unit, and when the power failure occurs, the AC power When this is blocked, the inverter control panel communication unit can be operated using the power supplied from the battery.

Another embodiment of the present invention constitutes a dual power supply by connecting a charger and a battery to AC power supplied to the inverter control panel communication unit, and when AC power is cut off in the event of a power failure, the inverter control panel uses DC power supplied from the battery. It is characterized by allowing the communication unit to operate.

The sensor is built in the inverter control panel communication unit, detects the amount of dissolved oxygen in the water in the fish farm, reservoir or dam, motor operation status, water temperature or water pollution level, and transmits the information to the database through the monitoring unit.

According to the present invention, air mixed with salt, impurities, etc., which has entered the air inlet, passes through an air circulation path through a filter to cool a lot of heat generated in the heat sink of the inverter to prevent malfunction of the inverter and stop of the inverter due to overheating. It has the effect.

According to the present invention, a preliminary power supply consisting of a charger and a battery connected to an AC power supply can be used to use power supplied from a power failure generator battery to prevent communication power interruption of the inverter control panel.

1 is a view showing a conventional inverter control panel air circulation.
Figure 2 is a view showing an inverter control panel overheating prevention device of the present invention.
Figure 3A is a view showing the air flow seen from the side of the inverter control panel.
Figure 3B is a view showing the air flow seen from the front of the inverter control panel.
Figure 3C is a three-dimensional view showing the air flow inside the inverter control panel.
4 is a view showing an inverter control panel communication unit in aquaculture monitoring system.
5 is a view showing an inverter control panel communication unit in the event of a power failure of FIG. 4;
Figure 6 is a view showing a dual power supply when the inverter control panel power off of the present invention.

Hereinafter, embodiments of the present invention will be described in detail based on the accompanying drawings.

1 is a structural diagram showing air circulation in a conventional inverter control panel, and FIG. 2 is a view showing a device for preventing overheating of the inverter control panel of the present invention.

3A is a view showing the air flow seen from the side of the inverter control panel, FIG. 3B is a view showing the air flow seen from the front of the inverter control panel, and FIG. 3C is a three-dimensional view showing the air flow inside the inverter control panel.

4 is a view showing an inverter control panel communication unit in aquaculture monitoring system, and FIG. 5 is a view showing an inverter control panel communication unit in the event of a power failure in FIG. 4.

6 is a view showing a dual power supply capable of supplying emergency power when the inverter control panel communication unit of the present invention is powered off.

As shown in FIG. 1, the inverter control panel 1 includes an inverter 2 inside a rectangular cabinet, a main breaker (not shown), a current transformer 4, a switching element 5, an overcurrent relay (EMPR, 6), Electronic devices such as transformers (TR, 7) are installed, and they are interconnected by wires or booths (BUS).

Air circulates directly above the end of the inverter control panel 1 or flows into both air passages 8 and 9 and rises above the inverter control panel 1. Since the inverter 2 is attached to the cabinet, a lot of heat is generated from the heat sink attached to the back of the inverter 2.

In particular, a lot of heat is generated when a lot of load is applied, and a large amount of heat is generated inside the inverter control panel 1, and when overheated, power may be cut off.

In order to maintain the performance of the inverter 2, it is preferable that heat generated in a plurality of electronic devices including a switching element is radiated rapidly.

2 is a view showing a device for preventing overheating of the inverter control panel of the present invention.

As shown in FIG. 2, the inverter control panel 20 of the present invention has an inverter 2, a main breaker (not shown), a current transformer 4, a switching element 5, and an overcurrent in the structure as shown in FIG. It includes electronic components such as a relay 6 and a transformer 7, and a communication unit 30 used in a monitoring device.

The difference between FIG. 2 and FIG. 1 is that, as shown in FIG. 3A, the heat sink 23 installed on the rear side of the inverter 2 is exposed to the air flow path 27 and installed so that the air introduced from the outside is the heat sink 23 It is characterized in that it is designed to quickly cool the high temperature heat inside the inverter control panel 20 while passing through.

2, the filter 26 is installed near the inside of the air inlets 24 and 25 installed on the lower side of the inverter control panel 20, and the air passing through the filter 26 is an inverter ( 1) It rises up inside and is discharged to the blowing fan 21, or through the air circulation path 27, hot air is quickly discharged out through the air discharge fan 22.

In addition, an air blower fan 21 and an air discharge fan 22 are installed on the inverter control panel 20 to quickly discharge hot heat generated from electronic components installed therein.

Meanwhile, the inverter control panel 20 includes an inverter control panel communication unit 30 for communication of a monitoring device.

The filter 26 installed in the air inlets 24 and 25 serves to prevent corrosion of electronic devices of the inverter control panel by removing dust, impurities, and salts mixed in the air.

Figure 3A is a view showing the air (air) flow seen from the side of the inverter control panel, Figure 3B is a view showing the air flow seen from the front of the inverter control panel, Figure 3C is a three-dimensional view showing the air flow inside the inverter control panel.

Air is introduced into the first air inlet 24 and the second air inlet 25 that are drilled on the lower side of the control panel. In the air inlet, two air inlets 24 and 25 are respectively installed at the lower end of the inverter 1 to allow air to enter the front and rear of the control panel 20.

In addition, as shown in 3A, the air entering the first air inlet 24 in front of the side comes out through a hole in the bottom of the inverter control panel 20 to cool the front part, and through the blowing fan 21 installed on the upper side Hot mixed air is discharged.

That is, the air entering the first air intake grid 28 and the first air inlet 24 on the side or front of the inverter control panel 20 comes out through the hole of the inverter control panel 20 to cool the front part, and the duct is the floor. It is discharged to the blowing fan 21 through the cotton hole.

On the other hand, air entering the rear of the inverter 2 through the second air intake grid 29 and the second air inlet 25 is discharged to the air exhaust fan 22 through the heat sink 23 of the inverter 2. .

The present invention is characterized by distinguishing the air inlet and outlet. When the air inlet and the outlet are separated, there is an advantage that the cooling effect of the inverter control panel 20 can be increased by reducing the resistance of the air flow.

4 is a view showing an inverter control panel communication unit in aquaculture monitoring system, and FIG. 5 is a view showing an inverter control panel communication unit in the event of a power failure in FIG. 4.

As shown in Fig. 4, the DC power supply 31 is generally supplied to the monitoring system of the farm. The DC power supply is 12 volts to 24 volts.

The inverter control panel communication unit 30 includes a program controller (PLC), a sensor 33, a monitoring unit (34), and a database (35).

A user may monitor information stored in the database 35 through the Internet using a smartphone or personal computer 36.

The sensor 33 built into the inverter control panel communication unit 30 detects the amount of dissolved oxygen contained in the water in the fish farm, reservoir or dam, the operating state of the motor, the temperature of the water, or the degree of contamination of the water, and provides information through the monitoring unit 34. To the database 35.

The inverter control panel communication unit 30 allows the user to grasp the amount of dissolved oxygen in the water in the fish farm, reservoir, or dam, the operating state of the motor, the temperature of the water, or the degree of contamination of the water through a smart phone or a personal computer 36 through the Internet communication. have.

When a user identifies a problem in a fish farm, reservoir or dam, the problem is solved by immediately instructing workers to solve the problem by wire or wireless at the site of the fish farm, reservoir or dam.

5 is a view showing an inverter control panel communication unit in the event of a power failure of FIG.

As shown in FIG. 5, when the power supplied to the inverter control panel communication unit 30 is cut off, the operation of the built-in program control unit 32, sensor 33, and monitoring unit 34 stops, so the monitoring system operates. This stops.

This makes it impossible for the user to monitor for alarms in fish farms, reservoirs or dams. Figure 6 solves the problems of the prior art when an outage occurs.

6 is a view showing a dual power supply for supplying emergency power when the power of the inverter control panel communication unit 30 of the present invention is cut off.

As illustrated in FIG. 6, when a power failure occurs in the inverter control panel communication unit 30, a charger 37 and a battery (charging) having a battery charging function in an AC power AC to solve a problem in which power is cut off ( 38) are connected in series.

If the AC power is cut off due to a power failure, the DC power stored in the battery 38 supplies emergency power to the PLC 32, the sensor 33, and the monitoring unit 34. This emergency power source can maintain the on-site alarm situation to the user until the AC power source is restored.

An embodiment of the present invention is characterized in that by constructing a double power supply consisting of a charger and a battery connected to AC power, the inverter control panel communication unit 30 is operated by using DC power supplied from the battery when a power failure occurs.

According to the present invention, the air inlets (24, 25) and the filter (27) are installed at the lower side surface of the inverter control panel, and the inflowing air passes through the air circulation path (27) through the filter (26), and the heat sink (23) of the inverter Since it can cool a lot of heat generated, there is an effect that can prevent the power off of the inverter control panel 20.

In addition, according to the present invention, by constructing a double power supply consisting of a charger 37 and a battery 38 connected to AC power, it is possible to use the power supplied from the battery 38 when a power outage occurs, so that the inverter control panel communication unit 30 It has the effect of preventing the power off.

1: cabinet 2: inverter
3: Main breaker 4: Current transformer (CT)
5: switching element 6: overcurrent relay (EMPR)
7: Transformer (TR) 10, 20: Inverter control panel
21: blower fan 22: air exhaust fan
23: heat sink 24: first air inlet
25: second air inlet 26: filter
27: air circuit 28: first air intake grid
29: second air suction grid 30: inverter control panel communication unit
31: DC power supply 32: Program control unit (PLC)
33: sensor 34: monitoring unit
34: database 36: smartphone or personal computer (PC)
37: Charger 38: Battery

Claims (3)

In the inverter control panel including the inverter, main circuit breaker, current transformer, overcurrent relay, transformer, switching element, monitoring device,
The first air inlet 24 and the second air inlet 25 installed on the lower side of the inverter control panel 20 and the first air suction grid 28 installed on the side or front of the inverter control panel 20) And a second air intake grid (29),
A filter 26 installed near the inside of the first air inlet 24 and the second air inlet 25,
The air circulation path 27 having a separate space to allow the air passing through the filter 26 to circulate, and the air passing through the air circulation path 27 heat the heat sink 23 of the inverter 2, An air discharge fan (22) for discharging the air containing the cooled heat;
It is installed on the upper end of the inverter control panel 20 comprises a blower fan 21 for discharging heat generated from electronic components, and an inverter control panel communication unit 30 for communication of the monitoring device, the inverter control panel ( The air entering the first air intake grid 28 and the first air inlet 24 of the side or front side of the air exits through the holes of the inverter control panel 20 to cool the front parts, and blows fans through the bottom holes. )
The air passing through the filter 26 enters the rear of the inverter 2 through the second air intake grid 29 and the second air inlet 25, and the air passes through the heat sink 23 of the inverter 2 It prevents overheating and dual power supply of the inverter control panel, characterized in that the heat generated from the heat sink (23) of the inverter (2) can be cooled by discharging to the exhaust fan (22).
According to claim 1, The inverter control panel communication unit 30 is composed of a program control unit 32, a sensor 33, a monitoring unit 34 and a database 35, the AC is supplied to the inverter control panel communication unit 30 Comprising a power supply including a charger 37 and the battery 38 is coupled to a dual power supply,
In the event of a power outage, when the AC power is cut off, the inverter control panel communication unit 30 can be operated by using the power supplied from the battery 38 to prevent overheating of the inverter control panel and the dual power supply device.
According to claim 2, The sensor 33 is built in the inverter control panel communication unit 30, and detects the amount of dissolved oxygen in the water in the fish farm, reservoir or dam, the state of the motor operation, the temperature of the water or the degree of contamination of the water, etc. Prevention of overheating and dual power supply of the inverter control panel, characterized in that information is transmitted to the database (35) through the monitoring unit (34).

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