KR20210039138A - Three-phase power conversion apparatus for base station - Google Patents

Abstract

The present invention relates to a three-phase power conversion device for a base station continuously supplying single- and three-phase power in case of a three-phase power failure and, more specifically, to a three-phase power conversion device for a base station continuously supplying single- and three-phase power in case of a three-phase power failure, which can continuously supply single- and three-phase power even in case that a failure occurs in at least one phase of three-phase power supplied by a transformer. To this end, disclosed is the three-phase power conversion device for a base station continuously supplying single- and three-phase power in case of a three-phase power failure. The three-phase power conversion device for a base station comprises: a first single-phase power supply for receiving three-phase power from a transformer and supplying first single-phase power to a single-phase load unit through a single-phase two-wire circuit breaker unit electrically connected to each phase of the three-phase power; a first three-phase power supply unit for supplying first three-phase power to a three-phase load unit through a three-phase and four-wire first power control unit electrically connected to each phase of the three-phase power; a second single-phase power supply for continuously supplying second single-phase power to the single-phase load unit even in case of a failure by selectively converting a phase with the lowest power demand among the remaining phases into single-phase power in case that at least one phase of the three-phase power fails, and outputting the single-phase power; and a second three-phase power supply unit for converting the second single-phase power, supplied from the second single-phase power supply, into three-phase power and supplying the same to the three-phase load unit through a three-phase and four-wire second power control unit.

Description

A three-phase power conversion apparatus for a base station that continuously supplies single-phase and three-phase power in the event of a three-phase power failure.

The present invention relates to a three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power when a three-phase power failure occurs, and more particularly, even when a failure occurs in at least one of the three-phase power supplied from a transformer. It relates to a three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power in the event of a three-phase power failure that can continuously supply single-phase power and three-phase power.

As disclosed in Korean Patent Laid-Open Publication No. 10-2007-0017594, a power supply device for a mobile communication system supplies 3-phase power supplied from a transformer and single-phase power obtained by converting 3-phase power to each equipment. At this time, in order to supply stable DC power to the mobile communication system, the battery is always maintained in a charged state as a spare power supply, and stable DC power is supplied in the event of a power outage.

However, battery charging/discharging characteristics deteriorate over time, and failure may occur in some cells of the battery, resulting in a problem that requires periodic inspection and management. In addition, when the life of the battery is over, there is a problem that the storage battery needs to be replaced again. Furthermore, a serious problem may occur if a problem occurs in the stable power supply during a power outage due to failure to detect an abnormality in the battery cell.

Republic of Korea Patent Publication No. 10-2007-0017594 (title of the invention: integrated power supply device for mobile communication system) Korean Registered Patent Publication No. 10-0540690 (Name of invention: power supply) Republic of Korea Public Utility Model Publication No. 96-3272 (Name of invention: Power converter for mobile communication base station)

Accordingly, the present invention was created to solve the above-described problems, and even when a failure occurs in the three-phase power supplied from the transformer, it is possible to stably and continuously supply three-phase power and single-phase power without using a storage battery or battery. Its purpose is to provide an invention.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

An object of the present invention described above is a first single-phase power supply unit that receives three-phase power from a transformer and supplies the first single-phase power to the single-phase load unit through a single-phase two-wire cut-off unit electrically connected to each phase of the three-phase power supply. , A first three-phase power supply that supplies the first three-phase power to the three-phase load unit through a three-phase four-wire first power control unit electrically connected to each phase of the three-phase power supply, and at least one of the three-phase power supply From the second single-phase power supply unit and the second single-phase power supply unit that continuously supply the second single-phase power to the single-phase load unit even in the event of a failure by selectively converting and outputting the phase with the least power demand among the remaining phases when a failure occurs. 3 characterized in that it comprises a second three-phase power supply unit converting the supplied second single-phase power into three-phase power and supplying the second three-phase power to the three-phase load unit through a three-phase four-wire second power control unit. This can be achieved by providing a three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power when a phase power failure occurs.

In addition, when the three-phase power supply is normally supplied, the first three-phase power is turned on through the three-phase four-wire first power control unit by turning on the three-phase four-wire first power control unit and turning off the three-phase four-wire second power control unit. It is to be supplied to the load unit, and the second three-phase power is not supplied to the three-phase load unit through the three-phase, four-wire second power control unit.

In addition, when a failure occurs in at least one of the three-phase power sources, the first three-phase power supply control unit is turned off and the second three-phase four-wire power control unit is turned on. In the event of a three-phase power failure, the single-phase and three-phase power is continuously supplied to the three-phase load unit, characterized in that it is not supplied to the three-phase load unit, and the second three-phase power is supplied to the three-phase load unit through a three-phase, four-wire second power control unit. To be supplied.

In addition, the first single-phase power supply unit is electrically connected to the transformer for each of the three phases, and a three-phase four-wire power cut-off unit that cuts off the power of each phase, and a three-phase four-wire power cut-off unit and a three-phase four-wire first power control unit. And a single-phase two-wire cut-off unit that is electrically connected to each phase to a power line electrically connected to each of the phases to supply the first single-phase power to the single-phase load unit.

In addition, the second single-phase power supply unit detects and calculates the power demand of each phase of the three-phase power supplied from the transformer, and when a failure occurs in at least one of the three-phase power sources, a power supply that selects the lowest power demand among the remaining phases. The selection and status sensing unit, and the three-phase four-wire power cut-off unit and the three-phase four-wire first power control unit are electrically connected to each phase to the power line electrically connected to each phase, and are used to control the power selection and state detection unit. And a power switching unit for outputting the second single-phase power switched from the three-phase power to the single-phase power based on the selected phase to the single-phase load unit.

In addition, the second three-phase power supply unit is a phase conversion unit that converts the second single-phase power supplied from the power transfer unit into a three-phase power supply, and the phase conversion unit is electrically connected to each other, and is supplied from the phase conversion unit. 2 It includes a three-phase four-wire second power control unit that is electrically connected to each phase of the output power line of the three-phase four-wire first power control unit to supply the three-phase power to the three-phase load unit.

According to the present invention as described above, even when a failure occurs in the three-phase power supplied from the transformer, it is possible to provide an invention capable of stably and continuously supplying three-phase power and single-phase power without using a storage battery or battery. .

In addition, according to the present invention, there is no need for periodic inspection or management like a battery, and there is no need for re-replacement such as when the storage battery or the battery has reached the end of its life, so it is more efficient than the battery operation in terms of management and cost. have.

The following drawings attached to the present specification illustrate a preferred embodiment of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so that the present invention is limited to the matters described in such drawings. It is limited and should not be interpreted.
1 is a diagram showing a schematic configuration of a three-phase power conversion apparatus for a base station according to an embodiment of the present invention,
2 is a single-phase power supply to a single-phase load through a single-phase two-wire cut-off unit and a three-phase power switch when there is no failure in the three-phase power supplied from the transformer according to an embodiment of the present invention or if the power failure is resolved. It is a drawing showing that,
FIG. 3 is a diagram illustrating that a three-phase power transfer unit is switched to a “S-phase” when a failure occurs in the "R phase" and the power demand of the "S phase" is the least according to an embodiment of the present invention. ,
FIG. 4 is a diagram illustrating that a three-phase power transfer unit is switched to a “T-phase” when a failure occurs in the "R phase" and the power demand of the "T phase" is the least according to an embodiment of the present invention. ,
FIG. 5 is a diagram illustrating that a single-phase power is supplied to a single-phase load through a three-phase power switch when there is no power failure or when a power failure is resolved according to an embodiment of the present invention, as a different example from FIG. 2.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings. In addition, one embodiment described below does not unreasonably limit the content of the present invention described in the claims, and the entire configuration described in the present embodiment cannot be said to be essential as a solution to the present invention. In addition, descriptions of the prior art and those that are obvious to those skilled in the art may be omitted, and descriptions of such omitted components (methods) and functions may be sufficiently referenced within the scope of the technical spirit of the present invention.

The three-phase conversion device that continuously supplies single-phase and three-phase power in the event of a three-phase power failure according to an embodiment of the present invention is continuous even when a failure occurs in one or two of the three-phase power supplied from the transformer. It is an invention that can continuously supply single-phase and three-phase. Hereinafter, a three-phase conversion device that continuously supplies single-phase and three-phase power when a three-phase power failure occurs according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, the first single-phase power supply unit is composed of a three-phase four-wire power cut-off unit and a first and second single-phase two-wire cut-off unit, and converts single-phase power to the first and second single-phase load units by the three-phase power supplied from the transformer. Supply. The 3-phase 4-wire power cut-off unit is electrically connected to the transformer and each phase, and can cut off the output of each phase if necessary. Each phase of the first and second single-phase two-wire cut-off parts is electrically connected to the output power line of the three-phase four-wire power cut-off part. That is, the single-phase two-wire cut-off unit is electrically connected to the R-phase and N-phase of the output power line of the three-phase four-wire cut-off unit to supply single-phase power to the single-phase load unit. In addition, the single-phase two-wire cut-off unit is electrically connected to the S-phase and N-phase of the output power line of the three-phase four-wire cut-off unit to supply single-phase power to the single-phase load unit. It is electrically connected to the T-phase and N-phase of the output power line of the 4-wire power cut-off unit to supply single-phase power to the single-phase load unit. At this time, as shown in Fig. 1, the first single-phase two-wire cut-off unit and the second single-phase two-wire cut-off unit are electrically connected to the output power lines of the three-phase four-wire power cut-off unit, respectively, to provide single-phase power to the first and second single-phase load units. Each can be supplied.

Meanwhile, since the first single-phase power supply unit converts the three-phase power supplied from the transformer into single-phase power through the single-phase two-wire cut-off unit and supplies it to each single-phase load unit, a failure occurs in any one of the three-phase power supplied from the transformer. In this case, the single-phase power cannot be supplied to the single-phase load unit. Referring to FIG. 1 as an example, FIG. 1 is a power supply device for supplying power to base station equipment disposed indoors, and the first single-phase load unit may be a communication device and an emergency battery device disposed in the base station as an example, and the second single-phase The load unit may be an RRU. The communication device and the emergency battery device are electrically connected to a single-phase power source among the R, S, and T phases of the first single-phase two-wire cut-off unit. At this time, assuming that the R phase is electrically connected, if a failure occurs in the R phase among the three phase power supplied from the transformer, a problem occurs in that single phase power cannot be supplied to the communication device and emergency battery device. Of course, in preparation for such an emergency, an emergency battery is provided, but the battery has several disadvantages. Accordingly, in the present invention, even when a failure occurs in any one of the supplied three-phase power sources, single-phase power can be continuously supplied, and will be described below.

The first three-phase power supply unit supplies the three-phase power supplied from the transformer as it is to the three-phase load unit (eg, an air conditioner or an air conditioner outdoor unit arranged for base station equipment). That is, the transformer and the three-phase four-wire power cut-off unit are all of the R, S, T, and N phases electrically connected to each other, and the three-phase four-wire power cut-off unit and the three-phase four-wire first power control unit are also R, S, T The three-phase power supplied from the transformer is supplied to the three-phase load by being electrically connected to each other in both the and N phases. At this time, when a failure occurs in any one of the three-phase power supplied from the transformer, there is a problem that the three-phase power cannot be supplied to the three-phase load unit. In order to solve this problem, in the present invention, a second single-phase power supply unit and a second three-phase power supply unit to be described later in the "failure state mode" are provided.

The above-described first single-phase power supply and the first three-phase power supply may supply single-phase and three-phase power to the base station equipment, respectively, in the "normal state mode" in which no failure occurs in the three-phase power supplied from the transformer. . Therefore, in the case of the "normal state mode", the first single-phase power supply path is the first single-phase power supplied to the single-phase load through the three-phase power supplied from the transformer sequentially through the three-phase four-wire power cut-off unit and the single-phase two-wire cut-off unit. . In addition, in the first three-phase power supply path, the three-phase power supplied from the transformer is sequentially passed through the three-phase four-wire power cut-off unit and the three-phase four-wire first power control unit, and the first three-phase power is supplied to the three-phase load. . At this time, all of the phases of the three-phase, four-wire first power control unit are in the "ON" state. At this time, the "ON" state means that each phase is electrically connected so that all of the three phases are supplied to the load unit.

The second single-phase power supply unit and the second three-phase power supply unit select one of the remaining phases that do not have a failure when a failure occurs in at least one of the three-phase power supplies supplied from the transformer, The phase is referred to as "transfer phase") and the second single-phase power supply and the second 3-phase power supply can be continuously supplied even in the "failure state mode" by converting the phase into three-phase power using the transfer phase, which will be described in detail below. .

The second single-phase power supply unit includes a power selection and state detection unit, and a three-phase power switching unit to supply the second single-phase power to the single-phase load unit. In addition, the second three-phase power supply unit includes a power selection and state detection unit, a three-phase power transfer unit, a phase conversion unit, and a three-phase four-wire second power control unit to supply the second three-phase power to the three-phase load unit. Supply. In addition to the above-described configuration, other components may be added for detailed description as necessary.

The power selection and state detection unit may include a failure detection unit, a power demand calculation unit, a phase transfer control unit, a phase cut-off control unit, an electric leakage and overload condition monitoring unit, a temperature monitoring unit, a battery capacity calculation unit, and a control unit.

The fault detection unit monitors each phase of the three-phase power supplied from the transformer, and detects when a fault occurs in one or more of the phases. As an example of this failure detection, by disposing a CT (current transformer) in each phase to sense the current of each phase, it is possible to detect which phase a failure has occurred.

The power demand calculator calculates the power demand for each phase using the current value sensed by the CT. By calculating the power demand for each phase, it is possible to select the phase to be transferred when a failure occurs.

The phase transfer control unit controls the three-phase power transfer unit to transfer to the phase selected by the phase transfer control unit by transmitting information on the "transfer phase" to the three-phase power transfer unit.

The phase cut-off control unit controls the three-phase, four-wire first and second power control units, respectively. In the "normal state mode", the 3-phase 4-wire first power control unit is turned "ON" and the 3-phase 4-wire second power control unit is turned "OFF". In the "failure state mode", the 3-phase 4-wire first power control unit is turned "OFF" and the 3-phase 4-wire second power control unit is turned "ON". At this time, "OFF" means that all of the phases are electrically open so that electricity does not flow, and "ON" means that all of the phases are electrically connected to allow electricity to flow.

The earth leakage and overload status monitoring unit monitors whether there is an earth leakage or overload in each phase through the current value sensed by the CT.

The temperature monitoring unit senses the temperature of the rack when the second single-phase power supply unit and the second three-phase power supply unit are each configured as a module and integrated into the rack.

The battery capacity calculation unit monitors the current state of the battery that can be used in an emergency and calculates the charging/discharging time of the battery.

Meanwhile, in the above-described example (referred to as the first embodiment), in the "normal state mode", the first single-phase power is supplied to the first single-phase load unit by the first single-phase power supply, so that the communication device and the battery can be operated. However, there is a problem in that the first single-phase power supply cannot supply single-phase power when a failure occurs in any one of the phases. Therefore, when "changing from the normal state mode to the fault state mode", the second single phase power supply is generated by the second single phase power supply unit and supplied to the first single phase load unit, thereby continuously supplying single phase power.

Referring to FIG. 5 as a second embodiment, the first single-phase load unit may be electrically connected only to the second single-phase power supply unit. That is, in the "normal state mode", the three-phase power transfer unit is transferred to the phase selected by the power selection and detection unit, so that the single-phase power generated by the three-phase power transfer unit is supplied to the first single-phase load unit, and Mode", the three-phase power transfer unit is transferred to the phase with the least power demand selected by the power selection and detection unit, so that the single-phase power generated by the three-phase power transfer unit is supplied to the first single-phase load unit. At this time, when the failed phase is restored, the three-phase power transfer unit is transferred to a preset phase in the "normal state mode" again, and supplies single-phase power to the first single-phase load unit. As described above, in the second embodiment, when the phase transfer control unit is in the "normal state mode or failure state mode", each phase to be transferred is selected to control the three-phase power transfer unit.

On the other hand, in the second embodiment, in the "normal state mode", the three-phase four-wire first power control unit is turned "ON" so that three-phase power is supplied to the three-phase load unit, and the three-phase four-wire second power control block " OFF". In addition, in the "failure state mode", the three-phase four-wire first power control unit is turned off and the three-phase four wire second power control unit is turned on to supply three-phase power to the three-phase load unit.

Each phase of the three-phase power transfer unit is electrically connected to a power line to which a three-phase four-wire power cut-off unit and a three-phase four-wire first power control unit are electrically connected to each other. The three-phase power switching unit is switched to a selected phase among the input three-phase power sources (see FIGS. 3 and 4), thereby supplying the second single-phase power to the first single-phase load unit.

The phase conversion unit converts the single phase transferred by the three-phase power transfer unit into a three-phase power supply and outputs it. The converted second three-phase power supply is supplied to a three-phase, four-wire second power control unit.

In the three-phase four-wire second power control unit, the phase conversion unit and each phase are electrically connected, and the output power line of the three-phase four-wire first power control unit and each phase are electrically connected. Therefore, in the "normal state mode", the three-phase, four-wire first power control unit is turned on (the three-phase four-wire second power control unit is turned off) to supply the first three-phase power to the three-phase load unit. In addition, in the "failure state mode", the 2nd 3-phase 4-wire power controller is "ON" (the 3-phase 4-wire first power controller is "OFF") to supply the 2nd 3-phase power to the 3-phase load part. It has the advantage of being able to continuously supply 3-phase power even in the event of a failure.

On the other hand, when there is no failure in the three-phase power supplied from the transformer, the power selection and state detection unit operates in the "normal state mode", and in the "normal state mode", the first single-phase power supply and the first three-phase power supply through the normal power loop Is supplied. The normal power loop is a loop that is supplied to a single-phase load by generating a first single-phase power passing through a transformer, a three-phase four-wire power cut-off unit, and a single-phase two-wire cut-off in sequence. In addition, the normal power loop is a loop that sequentially passes through a transformer, a three-phase four-wire power cut-off unit, and a three-phase four-wire first power control unit, and is supplied to the three-phase load by generating first three-phase power.

In the event of a failure in the three-phase power supplied from the transformer, the power selection and status detection unit operates in the “failure mode”, and in the “failure mode”, the second single-phase power and the second three-phase power are supplied through the faulty power loop. do. The fault power loop is a loop that sequentially passes through a transformer, a three-phase four-wire power cut-off unit, and a three-phase power transfer unit to generate a second single-phase power supply and supply it to a single-phase load. In addition, the faulty power loop generates a second three-phase power supply that sequentially passes through a transformer, a three-phase four-wire power cut-off unit, a three-phase power transfer unit, a phase conversion unit, and a three-phase four-wire second power control unit, and is thus a three-phase load. It is a loop that is supplied to.

When no failure occurs in the three-phase power supplied from the transformer, or when the power failure is resolved and restored, that is, in the case of the "normal state mode", the operation is performed as shown in FIG. 2 or 5. 2 shows that the first three-phase, four-wire power control unit is in the "ON" state, and the second three-phase, four-wire type power control unit is in the "OFF" state, and the first three-phase power is supplied through the first power control unit, and the first single-phase Power may be supplied through a single-phase two-wire cut-off unit or through a three-phase power transfer unit. Meanwhile, FIG. 5 shows that the three-phase power is supplied on the same principle as in FIG. 2, and that the single-phase power is supplied to the single-phase load only through the three-phase power switch. At this time, in order to supply single-phase power, the three-phase power transfer unit switches to a preset phase (basic mode phase) in "normal state mode" as described above and outputs single-phase power. In "failure state mode", power demand is reduced. Switches to the least phase (failure mode phase) and outputs single-phase power. When the fault is recovered, it is switched back to the basic mode, and the single-phase power is output.

When a failure occurs in the three-phase power supplied from the transformer, that is, in the case of a "failure state mode", the operation may be performed as shown in FIG. 3 or 4. 3 is an example of a case in which a failure occurs in the "R phase" and the power demand of the "S phase" is the least, and the three-phase power transfer unit is switched to the "S phase", thereby outputting a single-phase power supply of the S phase. FIG. 4 is an example of a case in which a failure occurs in the "R phase" and the power demand of the "T phase" is the least, and the three-phase power transfer unit is switched to the "T phase", thereby outputting a single-phase power supply of the T phase. On the other hand, if a failure occurs in two phases at the same time, it is switched over to the other phase. In addition, if a failure occurs in two phases sequentially over a period of time, the first phase is switched to the one with the least power demand among the remaining two phases, and then the phase is switched to the other phase in which the failure has not occurred.

In describing the present invention, descriptions of the prior art and those that are obvious to those skilled in the art may be omitted, and descriptions of these omitted components (methods) and functions will be sufficiently referenced within the scope not departing from the technical spirit of the present invention. I will be able to. In addition, the above-described elements of the present invention have been described for convenience of description of the present invention, and elements not described herein may be added within the scope not departing from the technical spirit of the present invention.

The descriptions of the configurations and functions of the respective parts have been described separately from each other for convenience of description, and one configuration and function may be implemented by being integrated into other components or further subdivided as necessary.

As described above, with reference to an embodiment of the present invention, the present invention is not limited thereto, and various modifications and applications are possible. That is, those skilled in the art will be able to easily understand that many modifications can be made without departing from the gist of the present invention. In addition, when it is determined that a detailed description of a known function related to the present invention and its configuration or a coupling relationship for each configuration of the present invention may unnecessarily obscure the subject matter of the present invention, it should be noted that the detailed description has been omitted. something to do.

Claims (6)

A first single-phase power supply unit receiving three-phase power from a transformer and supplying the first single-phase power to the single-phase load unit through a single-phase two-wire cut-off unit electrically connected to each phase of the three-phase power supply,
A first three-phase power supply unit for supplying first three-phase power to a three-phase load unit through a three-phase four-wire first power control unit electrically connected to each phase of the three-phase power supply,
A second single-phase for continuously supplying the second single-phase power to the single-phase load unit even when a failure occurs by selectively converting and outputting the phase with the least power demand among the remaining phases when a failure occurs in at least one of the three-phase power sources. Power supply, and
A second three-phase power supply that converts the second single-phase power supplied from the second single-phase power supply into three-phase power and supplies the second three-phase power to the three-phase load unit through a three-phase four-wire second power control unit. A three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power when a three-phase power failure occurs, comprising a unit.
The method of claim 1,
When the three-phase power is normally supplied, the three-phase four-wire first power control unit is turned on and the three-phase four-wire second power control unit is turned off. So that it is supplied to the upper load part,
3-phase power conversion for base stations that continuously supplies single-phase and 3-phase power in the event of a 3-phase power failure, characterized in that the second 3-phase power is not supplied to the 3-phase load unit through a 3-phase 4-wire second power control unit Device.
The method of claim 1,
When a failure occurs in at least one of the three-phase power sources, the three-phase four-wire first power control unit is turned off and the three-phase four-wire second power control unit is turned on. Make sure that the power is not supplied to the three-phase load part,
A three-phase power conversion device for base stations that continuously supplies single-phase and three-phase power in the event of a three-phase power failure, characterized in that the second three-phase power is supplied to the three-phase load unit through a three-phase four-wire second power control unit. .
The method of claim 3,
The first single-phase power supply unit,
Each of the three phases is electrically connected to the transformer, and a three-phase four-wire power cut-off unit that cuts off the power of each phase, and
The three-phase four-wire power cut-off unit and the three-phase four-wire first power control unit are electrically connected to each phase to a power line electrically connected to each other to supply the first single-phase power to the single-phase load unit. A three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power when a three-phase power failure occurs, comprising a single-phase two-wire cut-off unit.
The method of claim 4,
The second single-phase power supply unit,
A power supply selection and state detection unit that detects and calculates the power demand of each phase of the three-phase power supplied from the transformer, and selects a phase with the least power demand among the remaining phases when a failure occurs in at least one of the three-phase power supplies, and
The three-phase four-wire power cut-off unit and the three-phase four-wire first power control unit are electrically connected to each phase to a power line electrically connected to each other, based on the phase selected according to the control of the power selection and state detection unit. A base station that continuously supplies single-phase and three-phase power in the event of a three-phase power failure, comprising a power switching unit that outputs the second single-phase power converted from three-phase power to single-phase power to the single-phase load unit. For three-phase power conversion device.
The method of claim 5,
The second three-phase power supply unit,
A phase conversion unit for converting the second single-phase power supplied from the power transfer unit into a three-phase power supply, and
Each phase of the output power line of the three-phase four-wire first power control unit is electrically connected to the phase conversion unit and each phase to supply the second three-phase power supplied from the phase conversion unit to the three-phase load unit. A three-phase power conversion device for a base station that continuously supplies single-phase and three-phase power when a three-phase power failure occurs, comprising: the three-phase four-wire second power control unit electrically connected to the two.

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