JP2019161879A - Power converter - Google Patents

Abstract

To provide a PCS (power Conditioning System) which corresponds to fluctuations in cooling efficiency against the amount of heat in an inverter part due to fluctuations in an output voltage.SOLUTION: A power converter 100 includes: an inverter part 3 in which a DC power supplied from a power source is converted into an AC power to be supplied to a system 2; an output filter part 4 which is connected between the inverter part and the system and includes a reactor and a capacitor; a control part for controlling the inverter part; and a plurality of cooling fans 5 for cooling the inverter part, the output filter part and the control part. The control part includes: a voltage detection part for detecting an input voltage of the inverter part; a current detection part for detecting an output current of the inverter part; and a temperature detection part for detecting the outside air temperature. Based on at least one detected value of the input voltage of the inverter part, the output current of the inverter part, and the outside air temperature, the number of operating units of the plurality of cooling fans is determined.SELECTED DRAWING: Figure 1

Description

Conventionally, an uninterruptible power supply (UPS) is widely used as a power conversion device that stably supplies AC power to an important load such as a computer system. An uninterruptible power supply generally includes a converter unit that converts AC power supplied from a commercial power source into DC power, an inverter unit that converts DC power or DC power supplied from a battery into AC power, and each unit. And a plurality of cooling fans for cooling (see, for example, Patent Document 1).
In the power converter for indoor installation described in Patent Document 1, the control unit controls the cooling fan based on the load current and the fin temperature of the cooling fin provided in the inverter unit.
On the other hand, in the power converter for outdoor installation, in order to prevent wind and rain, an airtight cooling area in which the control unit is housed and an outside air cooling area in which the cooling fins and output filter unit provided in the inverter unit are housed are provided. Each area is individually provided with cooling means such as a cooling fan.

JP-A-2015-156746

However, in a power conversion device such as a PCS (Power Conditioning System), the output voltage from the solar panel constantly fluctuates, so the amount of heat generated from the inverter unit and the cooling efficiency required for the amount of heat generated are always constant. It will change. Therefore, the method of controlling the cooling means only by the load current and the temperature of the inverter portion as in Patent Document 1 cannot realize the optimum cooling efficiency.

  In order to solve the above problems, the present invention has the following technical features.

  An electric power converter according to the present invention includes an inverter unit that converts DC power supplied from a power source into AC power and supplies the AC power, and an output filter that is connected between the inverter unit and the system and includes a reactor and a capacitor. And a control unit that controls the inverter unit, and a plurality of cooling fan units that cool the inverter unit, the output filter unit, and the control unit, and the control unit determines an input voltage of the inverter unit. A voltage detection unit for detecting, a current detection unit for detecting an output current of the inverter unit, and a temperature detection unit for detecting an outside air temperature, the input voltage of the inverter unit, the output current of the inverter unit, the outside air The power converter is characterized in that the number of operating cooling fan units is determined based on at least one detected value of temperature.

By setting it as the above structures, an inverter part, an output filter part, and a control part can each be cooled by optimal cooling efficiency.

It is the schematic for demonstrating the structure of the power converter device which concerns on embodiment of this invention. It is the schematic for demonstrating operation | movement of the power converter device which concerns on embodiment of this invention. It is the schematic for demonstrating the table which shows the relationship between the detected value of the power converter device which concerns on embodiment of this invention, and the number of cooling fan operation | movement.

  Hereinafter, the present invention will be described through embodiments of the invention, but the invention according to the claims is not limited thereto. Moreover, not all the combinations of features described in the embodiments are essential for the solution means of the invention.

With reference to FIGS. 1-3, the power converter device 100 by embodiment which concerns on this invention is demonstrated.
<Configuration of power converter>
FIG. 1 is a schematic diagram illustrating a configuration of a power conversion apparatus 100 according to an embodiment of the present invention.

The power conversion device 100 includes an inverter unit 3, an output filter unit 4, a control unit 6, an inverter unit storage area 100a in which the inverter unit is stored, an output filter unit storage area 100b in which the output filter unit 4 is stored, and a control unit 6. The control unit storage area 100c and the cooling fan unit 5 are stored.
The solar panel 1 is connected to the input side of the inverter unit 3. The output side of the inverter unit 3 is connected to the system 2. An output filter 4 is inserted between the inverter unit 3 and the system 2, and a cooling fan unit 5 is connected between the output filter and the system 2. The solar panel 1 is a device that converts sunlight into electric power and outputs it, and the output voltage changes depending on the degree of solar radiation. The solar panel 1 is an example of the “power supply” in the claims. Moreover, the system | strain 2 is an example of the "load" of a claim.

 The inverter unit 3 includes a power conversion circuit that converts DC power into AC power. The power conversion circuit includes a semiconductor element such as an IGBT (Insulated Gate Bipolar Transistor) and converts the power by turning on and off the semiconductor element. On / off of the semiconductor element is controlled by the control unit 6 described later. The power conversion circuit may be a three-level power converter. Further, the AC power may be three-phase or single-phase. Further, the inverter unit 3 includes a cooling fin unit (not shown), and dissipates heat generated from the power conversion circuit through the cooling fin unit. The inverter unit 3 is stored in the inverter unit storage area 100a.

The output filter unit 4 includes a reactor 4a and a capacitor 4b, and reduces the harmonic current from the inverter unit 3. The output filter unit 4 is stored in the output filter unit storage area 100b.
The cooling fan unit 5 includes a first cooling fan unit, a second cooling fan unit, and a third cooling fan unit for cooling each of the inverter unit 3, the output filter unit 4, and the control unit 6. It is provided in the part storage area 100a, the output filter part storage area 100b, and the control part storage area 100c.

The control unit 6 controls the inverter unit 3 and the cooling fan unit 5 by a signal line (not shown). The control unit 6 is stored in the control unit storage area 100c.
The inverter unit storage area 100a is an area that is provided in the power conversion device 100 and in which the inverter unit 3 is stored. The inverter unit storage area 100a is an outside air cooling area that takes outside air into the power conversion apparatus 100 and cools it, and is an area that cools at least cooling fins included in the inverter unit 3 with the taken outside air. In addition, the inverter part accommodation area 100a is provided with the first cooling fan part described above, and the inverter part 3 is cooled when the cooling fan blows air to the cooling fins. For this reason, the inverter unit storage area 100a is provided with an intake port for the first cooling fan unit to intake air.

 The output filter unit storage area 100b is provided in the power conversion apparatus 100, and the output filter unit 4 is stored therein. The output filter unit storage area 100b is an outside air cooling area that takes outside air into the power conversion device 100 and cools it, and is an area for cooling at least the reactor 4a included in the output filter unit 4. The output filter unit storage area 100b stores the above-described second cooling fan unit, and the cooling fan blows air to the output filter unit 4, whereby the output filter unit 4 is cooled. Therefore, the output filter unit storage area 100b is provided with an intake port for the second cooling fan unit to intake air.

 The control unit storage area 100c is provided in the power conversion apparatus 100, and the control unit 6 is stored therein. In addition, a switch (not shown) is provided between the solar panel and the inverter unit, and between the cooling fan unit 5 and the system 2, and the switch is also stored in the control unit storage area 100c. Good. The opening / closing of each switch may be controlled by the control unit 6. The control unit storage area 100c is an airtight cooling area for cooling without directly taking outside air into the power conversion device 100, and is an area for cooling at least the control unit 6 and the above-described switch. The control unit storage area 100c is provided with the above-described third cooling fan unit, and the control unit 6 is cooled when the cooling fan blows air to the control unit 6 and the switch. Therefore, the control unit storage area 100c is provided with an intake port for the third cooling fan unit to intake air.

FIG. 2 is a schematic diagram illustrating a detailed configuration of the power conversion apparatus 100 according to the embodiment of the present invention. The same parts as those of the conventional power converter 100 shown in FIG.
Power conversion device 100 further includes a voltage detection unit 7, a current detection unit 8, and a temperature detection unit 9.
The voltage detection unit 7 is connected between the solar panel 1 and the inverter unit 3.
The current detection unit 8 is connected between the output filter unit 4 and the cooling fan unit 5.
The temperature detector 9 is provided so as to detect the outside air temperature. The temperature detection unit 9 is provided outside the power conversion device 100 and can be provided at any place of the power conversion device 100. Desirably, the temperature detection unit 9 may be installed so as to be approximately equal to the temperature of the outside air taken into the power conversion device 100 by the cooling fan unit 5. For example, the temperature detection unit 9 may be installed in the vicinity of the intake port provided in each storage area. By setting it as such a structure, since the temperature of the external air which the cooling fan part 5 takes in from the outside in the inside of a power converter device can be known directly, the operating number of the cooling fan parts 5 can be determined appropriately.

<Operation of power converter>
Next, the operation of the power conversion apparatus 100 will be described.
The solar panel 1 generates DC power from sunlight and supplies the DC power to the inverter unit 3.
The inverter unit 3 converts the DC power supplied from the solar panel 1 into AC power and outputs the AC power to the system 2.
The voltage detection unit 7 detects the output voltage of the solar panel 1, that is, the input voltage to the inverter unit 3, and transmits the detection value to the control unit 6.
The current detection unit 8 detects the output current of the inverter unit 3 and transmits the detected value to the control unit 6.
The outside temperature outside the temperature detection unit 9 and the power conversion device 100 is detected, and the detected value is transmitted to the control unit 6.

 The control unit 6 determines the number of operating cooling fan units 5 based on at least one of the input voltage of the inverter unit 3, the output current of the inverter unit 3, and the outside air temperature. Specifically, the number of cooling fan units 5 to be operated is determined based on a comparison between at least one of the input voltage of the inverter unit 3, the output current of the inverter unit 3, and the outside air temperature and a predetermined reference value. More specifically, the number of cooling fan units 5 to be operated is determined based on the input voltage of the inverter unit 3, the ratio of the output current of the inverter unit 3 to the rated output value, the operation upper limit voltage, or the operation lower limit voltage. As a ratio, for example, 50%, 70%, and 100% may be used as a reference. Furthermore, it is good also as not only this numerical value but the inverter part 3 operation | movement lower limit voltage, a rated voltage, and an operation | movement upper limit voltage. In this case, for example, the rated voltage is 750 V, the operating lower limit voltage is 570 V, and the operating upper limit voltage is 850 V. Even if the number of operating cooling fan units 5 is determined in advance based on a table showing the relationship between the number of operating cooling fan units 5 and the input voltage of inverter unit 3, the output current of inverter unit 3 and the outside air temperature. Good.

 In this way, by controlling the number of cooling fan units 5 to be operated, the cooling fans are not constantly operated, so that deterioration of the cooling fans over time is suppressed. Compared with the case where the cooling means is controlled only by the output current or the temperature of the inverter unit 3 by determining the number of cooling fan units to be operated in consideration of the input voltage of the inverter unit 3 that is influenced by sunlight or the like. And the inside of the power converter device 100 can be cooled efficiently.

FIG. 3 is a table showing the relationship between the number of operating cooling fan units 5 and the input voltage to the inverter unit, the output current of the inverter unit 3, and the outside air temperature. These are an example of the table in the case of outside temperature 40, 25, and -5 degreeC. The outside air temperature is determined by specifications such as the operating environment of the power conversion apparatus 100, but is not limited thereto. In addition, although the table shown in FIG. 3 showed the table in external temperature, ambient temperature of a cooling fin may be sufficient.
The control unit 8 determines and controls the number of operating cooling fan units 5 with reference to the input voltage to the inverter unit, which is the detected value, the output current of the inverter unit 3, the outside air temperature, and the table shown in FIG. .

Further, the number of operating units of the first cooling fin unit, the second cooling fin unit, and the third cooling fin unit stored in the inverter unit storage area 100a, the output filter unit storage area 100b, and the control unit storage area 100c are individually set. You may control. Note that the cooling fan whose operation is to be stopped may be set in consideration of the operation time up to that point, the replacement time, the presence or absence of a failure, and the like.
As mentioned above, although this invention was demonstrated along embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that changes or modifications can be made to the above embodiment.

DESCRIPTION OF SYMBOLS 1 Solar panel 2 System | strain 3, Inverter part 4 Output filter part 4a Reactor 4b Capacitor 5, Cooling fan part 6, Control part 7, Voltage detection part 8, Current detection part 9, Temperature detection part 100 Power converter device 100a Inverter part accommodation Area 100b Output filter storage area 100c Control storage area

The present invention relates to a power conversion device, and more particularly, to a power conversion device including a plurality of cooling fans and a cooling method thereof.

Conventionally, an uninterruptible power supply (UPS) is widely used as a power conversion device that stably supplies AC power to an important load such as a computer system. An uninterruptible power supply generally includes a converter unit that converts AC power supplied from a commercial power source into DC power, an inverter unit that converts DC power or DC power supplied from a battery into AC power, and each unit. And a plurality of cooling fans for cooling (see, for example, Patent Document 1) .

In the power conversion apparatus for indoor installation according to Patent Document 1, the control unit, the load current, based on the fin temperature of the cooling fins provided in the inverter unit, and controls the cooling fan.

In the power conversion apparatus for outdoor installation for this, because the weather protection, an airtight cooling area control unit is accommodated, the outside air cooling area of the cooling fins and an output filter unit provided in the inverter unit is housed Each area is provided with cooling means such as a cooling fan.

JP-A-2015-156746

However, in a power conversion device such as a PCS (Power Conditioning System), the output voltage from the solar panel constantly fluctuates, so the amount of heat generated from the inverter unit and the cooling efficiency required for the amount of heat generated are always constant. It will change. Therefore, the method of controlling the cooling means only by the load current and the temperature of the inverter portion as in Patent Document 1 cannot realize the optimum cooling efficiency.

  In order to solve the above problems, the present invention has the following technical features.

  An electric power converter according to the present invention includes an inverter unit that converts DC power supplied from a power source into AC power and supplies the AC power, and an output filter that is connected between the inverter unit and the system and includes a reactor and a capacitor. And a control unit that controls the inverter unit, and a plurality of cooling fan units that cool the inverter unit, the output filter unit, and the control unit, and the control unit determines an input voltage of the inverter unit. A voltage detection unit for detecting, a current detection unit for detecting an output current of the inverter unit, and a temperature detection unit for detecting an outside air temperature, the input voltage of the inverter unit, the output current of the inverter unit, the outside air The power converter is characterized in that the number of operating cooling fan units is determined based on at least one detected value of temperature.

By setting it as the above structures, an inverter part, an output filter part, and a control part can each be cooled by optimal cooling efficiency.

It is the schematic for demonstrating the structure of the power converter device which concerns on embodiment of this invention. It is the schematic for demonstrating operation | movement of the power converter device which concerns on embodiment of this invention. It is the schematic for demonstrating the table which shows the relationship between the detected value of the power converter device which concerns on embodiment of this invention, and the number of cooling fan operation | movement.

  Hereinafter, the present invention will be described through embodiments of the invention, but the invention according to the claims is not limited thereto. Moreover, not all the combinations of features described in the embodiments are essential for the solution means of the invention.

With reference to FIGS. 1-3, the power converter device 100 by embodiment which concerns on this invention is demonstrated.
<Configuration of power converter>
FIG. 1 is a schematic diagram illustrating a configuration of a power conversion apparatus 100 according to an embodiment of the present invention.

The power conversion device 100 includes an inverter unit 3, an output filter unit 4, a control unit 6, an inverter unit storage area 100a in which the inverter unit is stored, an output filter unit storage area 100b in which the output filter unit 4 is stored, and a control unit 6. The control unit storage area 100c to be stored and the cooling fan unit 5 are included .

Solar panel 1 is connected to the input side of the inverter unit 3. The output side of the inverter unit 3 is connected to the system 2. An output filter 4 is inserted between the inverter unit 3 and the system 2, and a cooling fan unit 5 is connected between the output filter and the system 2. The solar panel 1 is a device that converts sunlight into electric power and outputs it, and the output voltage changes depending on the degree of solar radiation. The solar panel 1 is an example of the “power supply” in the claims. Moreover, the system | strain 2 is an example of the "load" of a claim.

The inverter unit 3 includes a power conversion circuit that converts DC power into AC power. The power conversion circuit includes a semiconductor element such as an IGBT (Insulated Gate Bipolar Transistor) and converts the power by turning on and off the semiconductor element. On / off of the semiconductor element is controlled by the control unit 6 described later. The power conversion circuit may be a three-level power converter. Further, the AC power may be three-phase or single-phase. Further, the inverter unit 3 includes a cooling fin unit (not shown), and dissipates heat generated from the power conversion circuit through the cooling fin unit. The inverter unit 3 is stored in the inverter unit storage area 100a.

The output filter unit 4 includes a reactor 4a and a capacitor 4b, and reduces the harmonic current from the inverter unit 3. The output filter unit 4 is stored in the output filter unit storage area 100b .

Cooling fan unit 5, to cool the inverter unit 3, an output filter unit 4, each of the control unit 6 includes a first cooling fan unit, the second cooling fan unit, the third cooling fan unit, respectively The inverter unit storage area 100a, the output filter unit storage area 100b, and the control unit storage area 100c are provided.

The control unit 6 controls the inverter unit 3 and the cooling fan unit 5 by a signal line (not shown).
The control unit 6 is stored in the control unit storage area 100c.
The inverter unit storage area 100a is an area that is provided in the power conversion device 100 and in which the inverter unit 3 is stored. The inverter unit storage area 100a is an outside air cooling area that takes outside air into the power conversion apparatus 100 and cools it, and is an area that cools at least cooling fins included in the inverter unit 3 with the taken outside air. In addition, the inverter part accommodation area 100a is provided with the first cooling fan part described above, and the inverter part 3 is cooled when the cooling fan blows air to the cooling fins. For this reason, the inverter unit storage area 100a is provided with an intake port for the first cooling fan unit to intake air.

The output filter unit storage area 100b is provided in the power conversion apparatus 100, and the output filter unit 4 is stored therein. The output filter unit storage area 100b is an outside air cooling area that takes outside air into the power conversion device 100 and cools it, and is an area for cooling at least the reactor 4a included in the output filter unit 4. The output filter unit storage area 100b stores the above-described second cooling fan unit, and the cooling fan blows air to the output filter unit 4, whereby the output filter unit 4 is cooled. Therefore, the output filter unit storage area 100b is provided with an intake port for the second cooling fan unit to intake air.

The control unit storage area 100c is provided in the power conversion apparatus 100, and the control unit 6 is stored therein. In addition, a switch (not shown) is provided between the solar panel and the inverter unit, and between the cooling fan unit 5 and the system 2, and the switch is also stored in the control unit storage area 100c. Good. The opening / closing of each switch may be controlled by the control unit 6. The control unit storage area 100c is an airtight cooling area for cooling without directly taking outside air into the power conversion device 100, and is an area for cooling at least the control unit 6 and the above-described switch. The control unit storage area 100c is provided with the above-described third cooling fan unit, and the control unit 6 is cooled when the cooling fan blows air to the control unit 6 and the switch. Therefore, the control unit storage area 100c is provided with an intake port for the third cooling fan unit to intake air.

FIG. 2 is a schematic diagram illustrating a detailed configuration of the power conversion apparatus 100 according to the embodiment of the present invention. The same parts as those of the conventional power converter 100 shown in FIG. Power conversion device 100 further includes a voltage detection unit 7, a current detection unit 8, and a temperature detection unit 9 .

Voltage Detection unit 7 is connected between the solar panel 1 and the inverter unit 3.

Current detector 8 is connected between the output filter unit 4 and the cooling fan unit 5.

Temperature detection unit 9 is provided to detect the outside air temperature. The temperature detection unit 9 is provided outside the power conversion device 100 and can be provided at any place of the power conversion device 100. Desirably, the temperature detection unit 9 may be installed so as to be approximately equal to the temperature of the outside air taken into the power conversion device 100 by the cooling fan unit 5. For example, the temperature detection unit 9 may be installed in the vicinity of the intake port provided in each storage area. By setting it as such a structure, since the temperature of the external air which the cooling fan part 5 takes in from the outside in the inside of a power converter device can be known directly, the operating number of the cooling fan parts 5 can be determined appropriately.

<Operation of power converter>
Next, the operation of the power conversion apparatus 100 will be described.
The solar panel 1 generates DC power from sunlight and supplies the DC power to the inverter unit 3.
The inverter unit 3 converts the DC power supplied from the solar panel 1 into AC power and outputs the AC power to the system 2 .

Voltage Detection unit 7, the output voltage of the solar panel 1, i.e. detects an input voltage to the inverter unit 3, and transmits the detected value to the control unit 6.

Current detector 8 detects an output current of the inverter unit 3, and transmits the detected value to the control unit 6.
The outside temperature outside the temperature detection unit 9 and the power conversion device 100 is detected, and the detected value is transmitted to the control unit 6.

The control unit 6 determines the number of operating cooling fan units 5 based on at least one of the input voltage of the inverter unit 3, the output current of the inverter unit 3, and the outside air temperature. Specifically, the number of cooling fan units 5 to be operated is determined based on a comparison between at least one of the input voltage of the inverter unit 3, the output current of the inverter unit 3, and the outside air temperature and a predetermined reference value. More specifically, the number of cooling fan units 5 to be operated is determined based on the input voltage of the inverter unit 3, the ratio of the output current of the inverter unit 3 to the rated output value, the operation upper limit voltage, or the operation lower limit voltage. As a ratio, for example, 50%, 70%, and 100% may be used as a reference. Furthermore, it is good also as not only this numerical value but the inverter part 3 operation | movement lower limit voltage, a rated voltage, and an operation | movement upper limit voltage. In this case, for example, the rated voltage is 750 V, the operating lower limit voltage is 570 V, and the operating upper limit voltage is 850 V. Even if the number of operating cooling fan units 5 is determined in advance based on a table showing the relationship between the number of operating cooling fan units 5 and the input voltage of inverter unit 3, the output current of inverter unit 3 and the outside air temperature. Good.

In this way, by controlling the number of cooling fan units 5 to be operated, the cooling fans are not constantly operated, so that deterioration of the cooling fans over time is suppressed. Compared with the case where the cooling means is controlled only by the output current or the temperature of the inverter unit 3 by determining the number of cooling fan units to be operated in consideration of the input voltage of the inverter unit 3 that is influenced by sunlight or the like. And the inside of the power converter device 100 can be cooled efficiently.

FIG. 3 is a table showing the relationship between the number of operating cooling fan units 5 and the input voltage to the inverter unit, the output current of the inverter unit 3, and the outside air temperature. These are an example of the table in the case of outside temperature 40, 25, and -5 degreeC. The outside air temperature is determined by specifications such as the operating environment of the power conversion apparatus 100, but is not limited thereto. In addition, although the table shown in FIG. 3 showed the table in external temperature, ambient temperature of a cooling fin may be sufficient .

A control unit 8, the input voltage to the inverter unit is a detected value, the output current of the inverter unit 3, and the ambient air temperature, with reference to the table shown in FIG. 3, it determines to control the number of operating the cooling fan unit 5 To do.

Further, the number of operating units of the first cooling fin unit, the second cooling fin unit, and the third cooling fin unit stored in the inverter unit storage area 100a, the output filter unit storage area 100b, and the control unit storage area 100c are individually set. You may control. Note that the cooling fan whose operation is to be stopped may be set in consideration of the operation time until that time, the replacement time, the presence or absence of a failure, and the like.
As mentioned above, although this invention was demonstrated along embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that changes or modifications can be made to the above embodiment.

DESCRIPTION OF SYMBOLS 1 Solar panel 2 System | strain 3, Inverter part 4 Output filter part 4a Reactor 4b Capacitor 5, Cooling fan part 6, Control part 7, Voltage detection part 8, Current detection part 9, Temperature detection part 100 Power converter device 100a Inverter part accommodation Area 100b Output filter storage area 100c Control storage area

Claims (7)

An inverter unit that converts the DC power supplied from the power source into AC power and supplies it to the system;
An output filter unit connected between the inverter unit and the system, including a reactor and a capacitor,
A control unit for controlling the inverter unit;
A plurality of cooling fan units for cooling the inverter unit, the output filter unit and the control unit;
With
The controller is
A voltage detection unit for detecting an input voltage of the inverter unit;
A current detection unit for detecting an output current of the inverter unit;
A temperature detector for detecting the outside air temperature;
Including
Based on at least one detected value of the input voltage of the inverter unit, the output current of the inverter unit, and the outside air temperature, the number of operating cooling fans is determined.
The power converter characterized by the above-mentioned. The control device includes:
The operation number of the plurality of cooling fan units is determined based on a comparison between at least one detected value of the input voltage of the inverter unit, the output current of the inverter unit, and the outside air temperature and a predetermined reference value. The power conversion device according to claim 1. The control device includes:
Based on a table including the relationship between the output voltage of the power source, the output current of the inverter unit, the detected value of the outside air temperature and the number of operating cooling fan units, the number of operating cooling fan units is calculated. decide,
The power conversion device according to claim 1, wherein the power conversion device is a power conversion device. The plurality of cooling fan units are
A first cooling fan unit for cooling the inverter unit;
A second cooling fan section for cooling the output filter section;
A third cooling fan unit for cooling the control unit;
including,
The power conversion device according to any one of claims 1 to 3, wherein The power conversion device according to any one of claims 1 to 4,
An outside air cooling area,
An airtight cooling area,
With
The inverter unit and the output filter unit are housed in an outside air cooling area, and the control unit is housed in an airtight cooling area. The outside air cooling area and the airtight cooling area are:
There is an intake port for taking in outside air,
The power converter according to claim 1, wherein the temperature detection unit is provided in the vicinity of the intake port. The control device includes:
The number of operating cooling fans is determined based on an input voltage of the inverter, a rated voltage, an operating lower limit voltage, and an operating upper limit voltage of the inverter, and the number of operating cooling fans is determined. The power converter device described in 1.