WO2022195768A1

WO2022195768A1 - Power conversion system and maintenance assistance device

Info

Publication number: WO2022195768A1
Application number: PCT/JP2021/010847
Authority: WO
Inventors: 健志郎佐藤
Original assignee: 東芝三菱電機産業システム株式会社
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2022-09-22
Also published as: JPWO2022195768A1; CN115804253A

Abstract

This power conversion system is provided with: a power conversion device for converting power; an enclosure that has an internal space where the power conversion device is accommodated, and that has an air intake port for drawing outside air into the space, an exhaust port for discharging air inside the space to the outside of the space, and a filter provided inside the space so that the outside air drawn in from the air intake port passes therethrough; a fan for discharging the air inside the enclosure from the exhaust port, and drawing outside air into the enclosure from the air intake port; and a maintenance assistance device that has a measurement unit for measuring the extent of clogging of the filter, and a monitoring device for performing an alert operation of alerting that clogging of the filter has been sensed if the extent of clogging of the filter measured by the measurement unit has exceeded a threshold value. Provided thereby are a power conversion system and a maintenance assistance device that make it simple to ascertain the timing for maintenance of the filter.

Description

Power conversion system and maintenance aid

Embodiments of the present invention relate to a power conversion system and a maintenance assistance device.

A power conversion system is known that includes a power conversion device that converts power and a housing that houses the power conversion device in an internal space. A power conversion system is used, for example, in a photovoltaic power generation system. In a photovoltaic power generation system, a power converter converts DC power input from a solar panel into AC power and outputs the AC power to a power system. Such a power converter is called, for example, a power conditioner.

For example, the power converter and the housing are installed outdoors and used. The housing protects the power conversion device from wind, rain, dust, and the like by housing the power conversion device in an internal space.

A power conversion device, for example, has a plurality of switching elements, and performs power conversion by switching the plurality of switching elements. Moreover, when the temperature of the power conversion device reaches or exceeds a predetermined value, the power conversion device stops the operation of power conversion in order to protect each device such as a plurality of switching elements.

For this reason, in the power conversion system, a fan is provided to draw outside air into the housing to cool the power conversion device and prevent the power conversion device from stopping due to a temperature rise.

The housing has an intake port, an exhaust port, and a filter. The fan cools the power conversion device by discharging the air in the housing through the exhaust port and drawing outside air into the housing through the intake port. The filter is provided so that outside air taken in from the intake port passes through, and prevents dust and the like contained in the outside air from entering the housing.

In such a power conversion system, continued operation of the fan may cause clogging of the filter. If the filter becomes clogged, the power converter cannot be cooled appropriately, the temperature of the power converter rises, and there is a possibility that the power converter stops the power conversion operation. . Moreover, the load on the fan increases, which may lead to failure of the fan. Therefore, in the power conversion system, it is necessary to regularly perform filter maintenance such as cleaning and replacement to eliminate clogging of the filter.

However, it is very time-consuming for the administrator of the power conversion system to visually check the clogging of the filter one by one. In addition, when visually inspecting the clogging condition of the filter, the judgment of when to perform filter maintenance is left to the sensibilities of the manager or the like. For this reason, there is a concern that maintenance is performed more than necessary, which increases the trouble of administrators, etc. Conversely, maintenance is not performed even when it is necessary, and the filter may become clogged. be.

For this reason, in power conversion systems, it is desirable to be able to easily ascertain when filter maintenance is required.

WO2018/105010

Embodiments of the present invention provide a power conversion system and a maintenance assisting device that make it possible to easily grasp when filter maintenance is required.

According to an embodiment of the present invention, a power conversion device that converts power, an internal space that houses the power conversion device, an intake port for taking in outside air into the space, and a a housing having an exhaust port for discharging air to the outside of the space; and a filter provided in the space so that outside air taken in from the intake port passes through; A fan that discharges air from the exhaust port and draws outside air into the housing from the intake port, a measuring unit that measures the degree of clogging of the filter, and a degree of clogging of the filter measured by the measuring unit that exceeds a threshold value. There is provided a power conversion system comprising: a monitoring device that performs a notification operation to notify detection of clogging of the filter when the filter is clogged; and a maintenance auxiliary device having the monitoring device.

According to the embodiment of the present invention, a power conversion system and a maintenance assisting device are provided that allow a user to easily grasp when to perform filter maintenance.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which represents typically the power conversion system which concerns on embodiment. It is a flow chart which expresses typically an example of operation of a power conversion system concerning an embodiment. It is a block diagram which represents typically the modification of the power conversion system which concerns on embodiment. It is a block diagram which represents typically the modification of the power conversion system which concerns on embodiment. It is a block diagram which represents typically the modification of the power conversion system which concerns on embodiment.

Each embodiment will be described below with reference to the drawings.
Note that the drawings are schematic or conceptual, and the relationship between the thickness and width of each portion, the size ratio between portions, and the like are not necessarily the same as the actual ones. Also, even when the same parts are shown, the dimensions and ratios may be different depending on the drawing.
In addition, in the present specification and each figure, the same reference numerals are given to the same elements as those described above with respect to the already-appearing figures, and detailed description thereof will be omitted as appropriate.

FIG. 1 is a block diagram that schematically represents a power conversion system according to an embodiment.
As shown in FIG. 1 , the power conversion system 10 includes a power conversion device 12 , a housing 14 , a fan 16 , a maintenance assistance device 18 , a circuit breaker 20 and a transformer 22 .

The power conversion device 12 is connected to the power supply device 2 and is also connected to the power system 4 via the circuit breaker 20 and the transformer 22 . The power system 4 may be, for example, a factory load. The power supply device 2 is, for example, a solar panel. The power supply device 2 outputs DC power to the power conversion device 12 . A circuit breaker or the like may be provided between the power supply device 2 and the power conversion device 12 .

The power system 4 is, for example, an AC power system. The AC power of the power system 4 is, for example, three-phase AC power. The power conversion device 12 converts the DC power input from the power supply device 2 into AC power corresponding to the power system 4, and outputs the converted AC power to the power system 4 via the circuit breaker 20 and the transformer 22. . Thereby, the power conversion device 12 connects the power supply device 2 with the power system 4 .

The power converter 12 has, for example, a plurality of switching elements, and performs power conversion by switching the plurality of switching elements. Moreover, the power conversion device 12 has a housing 12a. The power conversion device 12 accommodates devices such as a plurality of switching elements in a housing 12a.

The power conversion device 12 also has a temperature sensor (not shown) that detects the temperature of internal devices such as switching elements. In other words, the temperature sensor detects the temperature inside the housing 12a. When the temperature detected by the temperature sensor reaches or exceeds a predetermined value, the power conversion device 12 stops the power conversion operation in order to protect each device such as a plurality of switching elements. In addition, the power conversion device 12 may have a plurality of temperature sensors. The power conversion device 12 may stop the power conversion operation when any one of the temperatures detected by the plurality of temperature sensors reaches or exceeds a predetermined value.

In this example, the power conversion system 10 includes two power converters 12 . The two power converters 12 are each connected to the power supply device 2 and connected to the power system 4 via the circuit breaker 20 and the transformer 22 . However, the number of power conversion devices 12 provided in the power conversion system 10 is not limited to two, and may be one or three or more. The number of power conversion devices 12 provided in the power conversion system 10 may be any number according to the magnitude of the DC power output from the power supply device 2 (power generation capacity of the solar panel).

The power supply device 2 is not limited to a solar battery panel, and may be other power generators such as wind power generators and gas turbine power generators. The power input to the power supply device 2 is not limited to DC power, and may be AC power. The power conversion device 12 may be configured to convert the AC power input from the power supply device 2 into another AC power corresponding to the power system 4 .

Also, the power supply device 2 may be, for example, a power storage device. For example, the power conversion device 12 converts the DC power input from the power supply device 2 into AC power corresponding to the power system 4, outputs the converted AC power to the power system 4, and inputs from the power system 4 The power supply device 2 may be charged by converting the AC power into DC power.

Also, the power supply device 2 may be, for example, another power system different from the power system 4 . The power conversion device 12 may be, for example, a frequency conversion device that connects two power systems with different frequencies. The power system 4 may be a DC power factory load or the like. The power conversion device 12 may be configured to convert the DC power supplied from the power supply device 2 into another DC power corresponding to the factory load. In this way, the conversion of electric power by the power conversion device 12 is not limited to conversion from direct current to alternating current, and may be arbitrary conversion. The configuration of the power conversion device 12 may be any configuration that converts power.

The circuit breaker 20 switches between a state in which the transformer 22 and each power converter 12 are connected to the power system 4 and a state in which the transformer 22 and each power converter 12 are disconnected from the power system 4 . The circuit breaker 20 is configured to disconnect the transformer 22 and each power conversion device 12 from the power system 4 when, for example, an abnormality occurs in any one of the power supply device 2, the power system 4, and the power conversion system 10. do.

The transformer 22 transforms the magnitude of the AC voltage output from each power conversion device 12 to the magnitude of the AC voltage according to the power system 4 .

Note that the power conversion system 10 does not necessarily have to include the circuit breaker 20 and the transformer 22 . The circuit breaker 20 and the transformer 22 may be provided separately from the power conversion system 10, for example. The circuit breaker 20 and the transformer 22 are provided as required and can be omitted.

The housing 14 has an internal space SP. The housing 14 is, for example, a substantially rectangular hollow box shape. The housing 14 may be called, for example, a package or an enclosure. The housing 14 accommodates each power conversion device 12 in an internal space SP. Housing 14 further houses circuit breaker 20 and transformer 22, for example. The housing 14 is installed outdoors and used. The housing 14 protects the power conversion device 12, the circuit breaker 20, the transformer 22, and the like housed in the space SP from wind, rain, dust, and the like. However, the housing 14 does not necessarily have to be installed outdoors. The housing 14 may be installed indoors for use.

The housing 14 further divides the space SP into three spaces, and accommodates each power conversion device 12, circuit breaker 20, and transformer 22 in separate spaces. However, the configuration of the housing 14 is not limited to the above. The housing 14 may accommodate each power converter 12, circuit breaker 20, and transformer 22 within one space SP. Further, the housing 14 does not necessarily have to house the circuit breaker 20 and the transformer 22 . The circuit breaker 20 and the transformer 22 may be housed and installed in a housing different from the housing 14 housing each power conversion device 12, for example. The configuration of the housing 14 may be any configuration capable of accommodating at least each power conversion device 12 .

The fan 16 cools the power conversion device 12 by drawing outside air into the housing 14 . As a result, the fan 16 prevents the power converter 12 from stopping the power conversion operation due to the temperature rise.

In this example, the fan 16 is provided in the power converter 12 . In other words, power converter 12 includes fan 16 . In this example, the power conversion system 10 includes two fans 16 corresponding to the two power converters 12, respectively. The fan 16 cools the power conversion device 12 by drawing outside air into the housing 14 and drawing the air inside the housing 14 into the housing 12 a of the power conversion device 12 .

However, the fan 16 may be provided in the housing 14 without being limited to the power converter 12 . In this case, one fan 16 may be provided for two power converters 12 . Also, the power conversion system 10 may include a plurality of fans 16, such as the fan 16 provided in the power converter 12 and the fan 16 provided in the housing 14, for example. The configuration of fan 16 may be any configuration that can adequately cool power converter 12 . The fan 16 may be configured so as to take in outside air at least into the space SP in which the power conversion device 12 is housed in the housing 14 . Also, the number of fans 16 may be any number that adequately cools the power converter 12 .

The housing 14 has an intake port 30, an exhaust port 32, and a filter 34. The intake port 30 and the exhaust port 32 are openings provided in the housing 14 so as to communicate the space SP inside the housing 14 with the outside of the housing 14 . The intake port 30 is an opening for taking outside air into the space SP. The exhaust port 32 is an opening for discharging the air inside the space SP to the outside of the space SP.

The intake port 30 and the exhaust port 32 are provided in the side portion of the housing 14, for example. In addition, the intake port 30 and the exhaust port 32 are provided with a member such as a hood or a louver for suppressing the direct entry of wind and rain into the housing 14 while suppressing the obstruction of passage of outside air. .

The fan 16 cools the power conversion device 12 by discharging the air inside the housing 14 through the exhaust port 32 and drawing outside air into the housing 14 through the intake port 30 .

The filter 34 is provided within the space SP of the housing 14 so that the outside air taken in from the intake port 30 passes through. As a result, the filter 34 prevents dust, salt, and the like contained in the outside air from entering the housing 14 . The filter 34 is, for example, a mesh member. The configuration of the filter 34 may be any configuration that allows outside air (air) to pass through while suppressing the passage of dust, salt, and the like contained in the outside air.

The filter 34 is provided near the intake port 30 within the housing 14, for example. The filter 34 is provided, for example, so as to face the intake port 30 and cover the intake port 30 . As a result, it is possible to prevent outside air taken in from the intake port 30 from entering the housing 14 without passing through the filter 34 .

However, the configuration of the filter 34 is not limited to the above. For example, a duct may be connected to the air inlet 30 and the filter 34 may be placed within the duct. The configuration such as the arrangement of the filter 34 may be any configuration that can appropriately suppress the entry of dust, salt, and the like contained in the outside air into the housing 14 .

In this example, the housing 14 has two air intakes 30 and two filters 34 provided corresponding to the two air intakes 30, respectively. However, the number of intake ports 30 and filters 34 is not limited to two, and may be one or three or more. Any number of inlets 30 and filters 34 may be used. Also, the number of filters 34 does not necessarily have to be the same as the number of inlets 30 . For example, one filter 34 may be provided for two inlets 30 . In other words, two air inlets 30 may be covered with one filter 34 . Conversely, two filters 34 may be provided for one air intake 30 . In other words, one intake port 30 may be covered with two filters 34 arranged side by side.

Also, in this example, the housing 14 has two exhaust ports 32 respectively corresponding to the two fans 16 provided in the two power converters 12 . The fan 16 is arranged, for example, facing the exhaust port 32 . As a result, the air inside the housing 14 can be efficiently discharged from the exhaust port 32 . However, the configuration of the fan 16 is not limited to this. The fan 16 may be configured to discharge the air in the housing 14 from the exhaust port 32 by being connected to the exhaust port 32 via a duct or the like, for example. For example, when the fan 16 is provided in the housing 14 , the fan 16 may be provided by being fitted in the exhaust port 32 . When the fan 16 is provided in the housing 14, the fan 16 may be provided on the outer surface side of the housing 14, for example. Also, the number of exhaust ports 32 does not necessarily have to be the same as the number of fans 16 . For example, two fans 16 may be arranged side by side with respect to one exhaust port 32 .

The maintenance auxiliary device 18 includes a differential pressure gauge 40 and a monitoring device 42. The differential pressure gauge 40 measures the differential pressure between the pressure on the front side of the filter 34 and the pressure on the back side of the filter 34 . More specifically, the front surface of the filter 34 is the surface on which outside air flows into the filter 34 . More specifically, the rear surface of the filter 34 is the surface from which outside air that has flowed into the filter 34 exits the filter 34 . The front surface of the filter 34 is, in other words, the surface that comes into contact with the outside air through the intake port 30 , and the back surface of the filter 34 is, in other words, the surface that comes into contact with the air inside the housing 14 . In other words, the differential pressure gauge 40 measures the pressure difference between the pressure on the side of the filter 34 into which the outside air flows and the pressure on the side of the filter 34 from which the outside air exits. More specifically, the pressure measured by the differential pressure gauge 40 is air pressure (static pressure).

As the fan 16 continues to operate, dust or the like adheres to the front side of the filter 34, causing clogging of the filter 34. When the filter 34 is clogged, the pressure on the front side of the filter 34 increases compared with the state in which the filter 34 is not clogged. and the pressure on the rear side of the filter 34 increases. As a result, the degree of clogging of the filter 34 can be measured by the differential pressure gauge 40 . In other words, the differential pressure gauge 40 functions as a measurement unit that measures the degree of clogging of the filter 34 .

The maintenance auxiliary device 18 includes two differential pressure gauges 40 corresponding to the two filters 34 respectively. The number of differential pressure gauges 40 is the same as the number of filters 34, for example. When a plurality of filters 34 are provided, the maintenance auxiliary device 18 measures the degree of clogging of each of the plurality of filters 34 by providing a plurality of differential pressure gauges 40 .

However, the number of differential pressure gauges 40 does not necessarily have to be the same as the number of filters 34 . For example, in a state in which a plurality of filters 34 are provided in the housing 14, if the change over time in the degree of clogging of the plurality of filters 34 is the same for each of the plurality of filters 34, the plurality of filters 34 One differential pressure gauge 40 may be provided for 34 . In other words, even when a plurality of filters 34 are provided, the degree of clogging of only one filter 34 may be measured as a representative.

The monitoring device 42 is provided within the space SP of the housing 14, for example. The monitoring device 42 is connected to each differential pressure gauge 40 and receives an input of the differential pressure measurement result from each differential pressure gauge 40 . The monitoring device 42 determines whether or not the differential pressure measured by the differential pressure gauge 40 is greater than or equal to the threshold. In other words, the monitoring device 42 determines whether the degree of clogging of the filter 34 measured by the differential pressure gauge 40 exceeds the threshold. The monitoring device 42 determines that the degree of clogging of the filter 34 exceeds the threshold when the differential pressure measured by the differential pressure gauge 40 is equal to or greater than the threshold. In other words, the monitoring device 42 detects clogging of the filter 34 when the differential pressure measured by the differential pressure gauge 40 is greater than or equal to the threshold.

For example, the monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold when the average value of the differential pressure measured by the differential pressure gauge 40 per predetermined time period is equal to or greater than the threshold. As a result, for example, it is possible to suppress erroneous detection due to an instantaneous change in differential pressure due to the influence of wind or the like. The monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold, for example, when the integrated value per predetermined time of the differential pressure measured by the differential pressure gauge 40 is equal to or greater than the threshold. Also in this case, erroneous detection can be similarly suppressed.

When the differential pressure measured by the differential pressure gauge 40 is greater than or equal to the threshold value, the monitoring device 42 performs a notification operation to notify detection of clogging of the filter 34 . In other words, the monitoring device 42 performs a notification operation to notify detection of clogging of the filter 34 when the degree of clogging of the filter 34 measured by the differential pressure gauge 40 exceeds the threshold value. The monitoring device 42 performs a notification operation, for example, when the degree of clogging of any one of the multiple filters 34 measured by the multiple differential pressure gauges 40 exceeds a threshold value. In other words, the monitoring device 42 performs a notification operation when detecting clogging of any one of the plurality of filters 34 . Note that the monitoring device 42 may perform a notification operation when the average value of the differential pressures or the integrated value of the differential pressures measured by the differential pressure gauge 40 is equal to or greater than a threshold value.

The monitoring device 42 is, for example, configured to be able to communicate with an external device 6 provided outside the housing 14 . Communication between the monitoring device 42 and the external device 6 may be wired or wireless. The monitoring device 42 performs, for example, transmission of a detection signal representing detection of clogging of the filter 34 to the external device 6 as a notification operation.

The external device 6 is, for example, a terminal such as a computer installed in a room where the administrator of the power conversion system 10 stands by. The external device 6 may be, for example, a mobile terminal carried by an administrator of the power conversion system 10 or the like. Alternatively, the external device 6 may be a host controller or the like that controls the power conversion system 10 in an integrated manner.

The external device 6 has a display unit such as a liquid crystal display, for example. In response to receiving the detection signal from the monitoring device 42 , the external device 6 displays characters, patterns, etc. indicating detection of clogging of the filter 34 on the display unit. As a result, the monitoring device 42 and the external device 6 notify the administrator or the like of the clogging of the filter 34 .

Note that, for example, when detecting clogging in any of the plurality of filters 34, the monitoring device 42 may include information about the filter 34 that detected clogging in the detection signal. Based on the information contained in the detection signal, the external device 6 notifies the clogged filter 34 by displaying on the display section which filter 34 out of the plurality of filters 34 is clogged. You may As a result, even when a plurality of filters 34 exist, it is possible to appropriately notify the administrator of the power conversion system 10 or the like of which filter 34 is clogged.

The mode of notification by the external device 6 is not limited to display on the display unit, and may be, for example, notification by sound using a speaker or the like, or notification by turning on or off light using a lamp or the like. The mode of notification by the external device 6 may be any mode that can appropriately notify the administrator or the like of the detection of clogging of the filter 34 .

Also, the monitoring device 42 is configured to be able to communicate with each power electronics device 12 . Communication between the monitoring device 42 and each power conversion device 12 may be wired or wireless. When the differential pressure measured by the differential pressure gauge 40 is equal to or higher than the threshold value, the monitoring device 42 performs a notification operation to notify the detection of clogging of the filter 34, and limits the output of each power conversion device 12. take action. The monitoring device 42 performs, for example, transmission of a detection signal to each power electronics device 12 as an output limiting operation.

Each power electronics device 12 limits the output power to a predetermined value or less in response to receiving the detection signal from the monitoring device 42 . Each power electronics device 12 limits the magnitude of AC power output to the power system 4 to a predetermined value or less, for example, in response to reception of a detection signal from the monitoring device 42 . Note that the output limiting operation by the monitoring device 42 is not limited to the transmission of the detection signal to each power converter 12, and may be any action that allows each power converter 12 to limit the output.

FIG. 2 is a flowchart that schematically represents an example of the operation of the power conversion system according to the embodiment.
In the power conversion system 10 , each power conversion device 12 converts DC power input from the power supply device 2 into AC power corresponding to the power system 4 and outputs the converted AC power to the power system 4 . At this time, each power converter 12 drives the fan 16 . Each fan 16 cools each power conversion device 12 by exhausting the air in the housing 14 through the exhaust port 32 and drawing outside air into the housing 14 through the intake port 30 .

In the power conversion system 10, a filter 34 is provided in the housing 14, and when each power conversion device 12 is cooled by driving each fan 16, dust and salt contained in the outside air enter the housing 14. is suppressed by filter 34 .

Furthermore, in the power conversion system 10, each differential pressure gauge 40 of the maintenance auxiliary device 18 measures the differential pressure between the pressure on the front side of the filter 34 and the pressure on the back side of the filter 34 (step S101 in FIG. 2). Each differential pressure gauge 40 inputs the measurement result of the differential pressure of each filter 34 to the monitoring device 42 .

The monitoring device 42 determines whether or not the differential pressure of each filter 34 measured by each differential pressure gauge 40 is greater than or equal to the threshold value (step S102 in FIG. 2). The monitoring device 42 may determine whether or not the average value of the differential pressure or the integrated value of the differential pressure is greater than or equal to the threshold value. When the monitoring device 42 determines that it is less than the threshold value, the monitoring device 42 repeats the determination process based on the measurement result of each differential pressure gauge 40 .

On the other hand, when the monitoring device 42 determines that any one of the filters 34 is equal to or greater than the threshold value, the monitoring device 42 transmits a detection signal indicating detection of clogging of the filter 34 to the external device 6 to detect clogging of the filter 34. A notification operation for notifying the detection is performed (step S103 in FIG. 2).

Upon receiving the detection signal from the monitoring device 42, the external device 6 notifies the administrator or the like of the clogging of the filter 34 by displaying characters, patterns, etc. on the display unit.

As a result, in the power conversion system 10 and the maintenance auxiliary device 18, the administrator or the like can eliminate the trouble of visually inspecting the degree of clogging of the filter 34 one by one. If the transmission of the detection signal to the external device 6 is used as the notification operation, for example, it is possible to eliminate the trouble of going to the housing 14 installed outdoors, for example. For example, a manager or the like can grasp the clogging of each filter 34 while staying in the management room or the like without going to the housing 14 .

Also, the judgment of when to perform maintenance on the filter 34 is not left to the sensibilities of the administrator or the like. Therefore, the maintenance timing of the filter 34 can be properly grasped. For example, maintenance is performed more than necessary, which increases the time and effort of an administrator, and conversely, maintenance is not performed even when it is necessary, and each filter 34 is prevented from clogging. can do.

Thus, with the power conversion system 10 and the maintenance assisting device 18 according to the present embodiment, it is possible to easily grasp the timing of maintenance of each filter 34 . This allows the administrator of the power conversion system 10 or the like to perform maintenance of each filter 34 at an appropriate timing. As a result, for example, it is possible to prevent the filters 34 from clogging, causing the temperature of each power conversion device 12 to rise, and causing each power conversion device 12 to stop the power conversion operation. Furthermore, it is possible to prevent the load on each fan 16 from increasing due to the clogging of each filter 34 and the failure of each fan 16 . For example, when the fan 16 is provided in the power converter 12 , detection of a failure of the fan 16 may cause the power converter 12 to stop the power conversion operation. By suppressing the failure of the fan 16 due to the clogging of the filter 34, the stop of the power conversion operation of the power converter 12 due to the failure of the fan 16 can also be suppressed.

In addition, when the monitoring device 42 determines that any of the filters 34 is equal to or greater than the threshold value, the monitoring device 42 performs a notification operation and performs an output limiting operation to limit the output of each power conversion device 12 (step S104 in FIG. 2). .

Each power conversion device 12 limits the magnitude of the AC power output to the power system 4 to a predetermined value or less, for example, in response to receiving a detection signal from the monitoring device 42 . Thereby, an increase in the temperature of each power conversion device 12 can be suppressed. For example, the temperature of each power conversion device 12 rises and each power It is possible to prevent the converter 12 from stopping the power conversion operation.

The monitoring device 42 performs a notification operation when the clogged filter 34 is maintained and the differential pressure (the average value of the differential pressure or the integrated value of the differential pressure) of each filter 34 becomes less than the threshold value. and end the output limiting operation. In other words, the monitoring device 42 stops transmission of the detection signal to the external device 6 and each power converter 12 when the differential pressure of each filter 34 becomes less than the threshold. The power conversion system 10 and the maintenance assistance device 18 repeat the same processing thereafter.

FIG. 3 is a block diagram schematically showing a modification of the power conversion system according to the embodiment.
As shown in FIG. 3, in the power conversion system 10a and the maintenance auxiliary device 18a, the differential pressure gauge 40 is replaced with an air flow meter 40a. It should be noted that the same reference numerals are given to the parts that are substantially the same as those of the above-described embodiment in terms of function and configuration, and detailed description thereof will be omitted.

The air volume meter 40a measures the volume of outside air flowing into the housing 14 through the filter 34. As the fan 16 continues to operate, dust or the like adheres to the front side of the filter 34, causing clogging of the filter 34. When the filter 34 is clogged, the amount of air that passes through the housing via the filter 34 is reduced compared to when the filter 34 is not clogged. The air volume of the outside air flowing into 14 decreases. As a result, the degree of clogging of the filter 34 can also be measured by the air volume meter 40a. The air flow meter 40a also functions as a measurement unit that measures the degree of clogging of the filter 34 .

The monitoring device 42 receives an input of the air volume measurement result from the air volume meter 40a. The monitoring device 42 determines whether the air volume measured by the air volume meter 40a is less than the threshold. The monitoring device 42 determines that the degree of clogging of the filter 34 exceeds the threshold when the air volume measured by the air flow meter 40a is less than the threshold. In other words, the monitoring device 42 detects clogging of the filter 34 when the air volume measured by the air volume meter 40a is less than the threshold value.

For example, the monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold when the average value of the air volume measured by the air volume meter 40a per predetermined time period is less than the threshold. For example, the monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold when the integrated value of the air volume measured by the air flow meter 40a per predetermined time is less than the threshold. As a result, erroneous detection can be suppressed.

When the air volume measured by the air flow meter 40a is less than the threshold value, the monitoring device 42 performs a notification operation of notifying the detection of clogging of the filter 34 and an output restriction operation of restricting the output of each power conversion device 12. .

In this way, the measurement unit that measures the degree of clogging of the filter 34 is not limited to the differential pressure gauge 40, but may be the air flow meter 40a. The measurement unit may be, for example, an anemometer. The monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold when the wind speed measured by the anemometer is less than the threshold.

The measurement unit may be, for example, an optical sensor. When the filter 34 is clogged, the amount of light (brightness) entering the housing 14 through the filter 34 is reduced compared to when the filter 34 is not clogged. Monitoring device 42 may determine that the degree of clogging of filter 34 has exceeded a threshold when the amount of light measured by the light sensor is less than the threshold.

The measurement unit may be, for example, an ammeter that measures the magnitude of the current supplied to the fan 16. When the filter 34 is clogged, the load on the fan 16 increases compared to when the filter 34 is not clogged, and there is a possibility that the current required to rotate the fan 16 at a predetermined speed will increase. be. The monitoring device 42 may determine that the degree of clogging of the filter 34 has exceeded the threshold when the magnitude of the current measured by the ammeter is equal to or greater than the threshold.

For example, a rotation speed measuring device that measures the rotation speed of the fan 16 is used as a measurement unit, and when the rotation speed of the fan 16 while supplying constant power to the fan 16 becomes less than a threshold value, the filter 34 It may be determined that the degree of clogging exceeds a threshold. In this way, when measuring the degree of clogging of the filter 34 in accordance with changes in the load on the fan 16, the function of the monitoring device 42 may be incorporated in, for example, a driving unit that drives the fan 16. FIG.

The measurement unit is not limited to the above, and may be any device capable of appropriately measuring the degree of clogging of the filter 34. The configuration of the monitoring device 42 may be any configuration that can determine whether or not the degree of clogging of the filter 34 exceeds the threshold based on the measurement result of the measurement unit.

FIG. 4 is a block diagram schematically showing a modification of the power conversion system according to the embodiment.
As shown in FIG. 4 , in the power conversion system 10b and the maintenance auxiliary device 18b, the external device 6 is omitted, and the monitoring device 42 is provided with the notification unit 44 . In other words, the monitoring device 42 has a notification unit 44 in this example.

In this example, when the monitoring device 42 determines that the degree of clogging of the filter 34 has exceeded the threshold value, the notification unit 44 performs notification as a notification operation for notifying detection of clogging of the filter 34 .

The notification unit 44 is, for example, a display unit, and notifies the administrator or the like of detection of clogging of the filter 34 by displaying characters, patterns, or the like indicating detection of clogging of the filter 34 . However, the form of notification by the notification unit 44 is not limited to the display of characters, patterns, etc., and may be, for example, notification by voice using a speaker or the like, or notification by turning on or off light using a lamp or the like. good. The mode of reporting by the reporting unit 44 may be any mode capable of appropriately reporting the detection of clogging of the filter 34 to an administrator or the like.

In this way, the notification operation by the monitoring device 42 is not limited to transmission of the detection signal to the external device 6, but may be notification by the notification unit 44 provided in the monitoring device 42, or the like. The notification operation by the monitoring device 42 is not limited to the above, and may be any operation that can appropriately notify the administrator or the like of the power conversion system of the detection of clogging of the filter 34 .

The notification unit 44 may be provided on the outer surface side of the housing 14, for example. As a result, the administrator of the power conversion system 10b can grasp the timing of maintenance of each filter 34 from the outside of the housing 14 without entering the housing 14 one by one.

FIG. 5 is a block diagram schematically showing a modification of the power conversion system according to the embodiment.
As shown in FIG. 5, in the power conversion system 10c and the maintenance auxiliary device 18c, the monitoring device 42 is arranged outside the housing 14. As shown in FIG. In this example, the monitoring device 42 is, for example, a terminal such as a computer installed in a room where an administrator of the power conversion system 10c waits, a mobile terminal carried by an administrator of the power conversion system 10c, or a power converter. A high-level controller or the like that comprehensively controls the system 10c. In other words, the external device 6 of the above embodiment may be used as the monitoring device 42 .

In this example, the monitoring device 42 is configured to be able to communicate with the differential pressure gauge 40 (measurement section). Communication between the monitoring device 42 and the differential pressure gauge 40 may be wired or wireless. The monitoring device 42 communicates with the differential pressure gauge 40 and receives an input of the differential pressure measurement result from the differential pressure gauge 40 to determine whether the degree of clogging of the filter 34 exceeds a threshold value.

Thus, the monitoring device 42 does not necessarily have to be provided inside the housing 14 . The monitoring device 42 may be provided outside the housing 14 .

Each of the above embodiments shows an example in which the present invention is applied to the housing 14 that is installed and used outdoors. The present invention is not limited to this, and may be applied, for example, when an intake port, an exhaust port, and a filter are provided in the housing 12a of the power conversion device 12 . In other words, the power conversion device 12 of each embodiment described above is used as a power conversion system, and the power conversion unit such as a plurality of switching elements provided in the housing 12a of the power conversion device 12 is used as a power conversion device, and the present invention is applied. You may

Although several embodiments of the invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and equivalents thereof.

Claims

a power conversion device that converts power;
having an internal space for housing the power conversion device, an intake port for taking in outside air into the space, an exhaust port for discharging the air in the space to the outside of the space, and from the intake port a housing having a filter provided in the space so that outside air taken in passes through;
a fan that exhausts air in the housing from the exhaust port and draws outside air into the housing from the intake port;
a measuring unit that measures the degree of clogging of the filter; and a monitoring device that performs a notification operation of notifying detection of clogging of the filter when the degree of clogging of the filter measured by the measuring unit exceeds a threshold; a maintenance aid having
A power conversion system with
2. The monitoring device according to claim 1, wherein when the degree of clogging of the filter measured by the measuring unit exceeds a threshold value, the monitoring device performs the notification operation and performs an output limiting operation for limiting the output of the power conversion device. power conversion system.
The measuring unit is a differential pressure gauge that measures the differential pressure between the pressure on the front side of the filter and the pressure on the back side of the filter,
2. The power conversion system according to claim 1, wherein the monitoring device determines that the degree of clogging of the filter exceeds a threshold when the differential pressure measured by the differential pressure gauge is equal to or greater than a threshold.
2. The monitoring device is configured to be able to communicate with an external device provided outside the housing, and transmits a detection signal indicating detection of clogging of the filter to the external device as the notification operation. A power conversion system as described.
The power conversion system according to claim 1, wherein the monitoring device has a notification unit, and the notification by the notification unit is performed as the notification operation.
The power conversion system according to claim 5, wherein the monitoring device is arranged outside the housing.
a power conversion device that converts power;
having an internal space for housing the power conversion device, an intake port for taking in outside air into the space, an exhaust port for discharging the air in the space to the outside of the space, and from the intake port a housing having a filter provided in the space so that outside air taken in passes through;
a fan that exhausts air in the housing from the exhaust port and draws outside air into the housing from the intake port;
A maintenance auxiliary device used in a power conversion system comprising
a measuring unit for measuring the degree of clogging of the filter;
a monitoring device that performs a notification operation of notifying detection of clogging of the filter when the degree of clogging of the filter measured by the measuring unit exceeds a threshold;
A maintenance aid with