JP6709992B2 - Decentralized power generation system - Google Patents

Description

The present disclosure relates to distributed power generation systems.

A solar power generation system is known that generates DC power and converts the generated DC power into AC power. Patent Document 1 describes that the output current from the photovoltaic power generation system is specified by the first current detector. Further, Patent Document 1 describes that another current detector is also provided, and an error in the mounting attitude (installation direction) of the first current detector is detected using the detection values of these two current detectors. ing.

Japanese Patent No. 5850234

The present inventor is considering combining a solar power generation system and a fuel cell system to form a distributed power generation system. However, according to the study by the present inventor, the technique of Patent Document 1 that detects an error in the mounting posture of the first current detector by using the detection values of the two current detectors is not necessarily applicable to this distributed power generation system. Not suitable.

In view of such circumstances, the present disclosure provides a technique suitable for the error detection of the mounting attitude of the current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system as described above. To aim.

That is, the present disclosure is
A distributed power generation system that is connected to a single-phase three-wire power system,
The distributed power generation system includes a solar power generation system, a fuel cell system, a first current detector, a first voltage specifying unit, and a control unit.
Each of the solar power generation system and the fuel cell system generates direct current power and converts the direct current power into alternating current power,
There is a single-phase three-wire first electric line connecting the electric power system and the solar power generation system,
There is a single-phase three-wire type second electric circuit that connects the fuel cell system and the first electric circuit,
Each of the first electric line and the second electric line is a combination of a ground line, a first voltage line and a second voltage line, and a first AC voltage is applied between the ground line and the first voltage line. Have a combination that is
The first voltage identifying unit identifies the first AC voltage,
The first current detector is attached to a first detection position, and specifies a current flowing through a connection point between the solar power generation system and the first voltage path of the first electric line,
When the current specified by the first current detector is defined as a first specific current and the first AC voltage specified by the first voltage specifying unit is defined as a first specific voltage, the control unit is configured to control the 1 specific current and 1st active power which is active power of the 1st specific voltage are calculated, and the 1st active power is below the 1st threshold power from the time when the 1st active power becomes below the 1st threshold power. When the state of is continued for the first threshold period, it is determined that the mounting posture of the first current detector to the first detection position is wrong,
The first threshold power is a value less than zero,
The first threshold period provides a distributed power generation system having a value of zero or more.

The technology according to the present disclosure is to detect an error in the mounting posture of the first current detector that specifies the output current from the photovoltaic power generation system in a distributed power generation system that combines a photovoltaic power generation system and a fuel cell system. Suitable for

Configuration diagram of the distributed power generation system of the embodiment Configuration diagram of control unit Flow diagram for explaining power correction Flow diagram to explain how the phase information is changed Diagram for explaining the calculation of active power Configuration diagram of distributed power generation system of comparative form

(Findings by the present inventor)
The present inventor examined a distributed power generation system 500 of a comparative form as shown in FIG. The distributed power generation system 500 can be interconnected with a single-phase three-wire power system 499. The distributed power generation system 500 includes a solar power generation system 520, a fuel cell system 530, a control unit 540, a display unit (display device) 550, a distribution board 560, a load 570, and a current detector 581. It has a current detector 583, a current detector 584, a voltage specifying unit 585, and a voltage specifying unit 586.

The solar power generation system 520 includes a power generator 521 and a power conditioner 522. The generator 521 is a solar panel. The generator 521 generates DC power. The power conditioner 522 converts this DC power into AC power.

The fuel cell system 530 has a generator 531 and a power conditioner 532. The generator 531 is a fuel cell. The generator 531 generates DC power. The power conditioner 532 converts this DC power into AC power.

The distribution board 560 has a solar cell branch breaker (PV branch breaker) 561, a main breaker 562, and a fuel cell breaker 563.

There is a single-phase three-wire first electric line 591 that connects the electric power system 499 and the solar power generation system 520. There is a single-phase three-wire type second electric line 592 that connects the fuel cell system 530 and the first electric line 591. There is a third circuit 593 connecting the load 570 and the second circuit 592. In the PV branch breaker 561, the first electric line 591 and the second electric line 592 are connected. In the main breaker 562, the second electric line 592 and the third electric line 593 are connected. Each of the first electric line 591 and the second electric line 592 has a combination of a ground line, a first voltage line and a second voltage line. A first AC voltage is applied between the ground path and the first voltage path. A second AC voltage is applied between the ground path and the second voltage path.

The current detector 581 identifies the current flowing through the connection point between the solar power generation system 520 and the first voltage path of the first electric path 591. The current detector 583 is provided at a position between the PV branch breaker 561 and the main breaker 562 in the first voltage path of the second electric path 592. The current detector 584 is provided at a position between the PV branch breaker 561 and the main breaker 562 in the second voltage path of the second electric path 592.

The voltage identification unit 585 identifies the first AC voltage. The voltage identifying unit 586 identifies the second AC voltage.

If current always flows in the position between the PV branch breaker 561 and the main breaker 562 in the first voltage path of the second electric path 592, the detected value of the current detector 581 and the detected value of the current detector 583 are assumed. There is room for detecting an error in the mounting posture of the current detector 581 using. However, in a system including both the solar power generation system 520 and the fuel cell system 530, the AC power generated by the fuel cell system 530 may not be allowed to flow backward to the power system 499. Therefore, the AC power generated in the fuel cell system 530 may be adjusted so that the current does not flow in the position between the PV branch breaker 561 and the main breaker 562. In such a case, the detected value of the current detector 583 is maintained at zero, and therefore the detected value of the current detector 581 and the detected value of the current detector 583 are used to correct the mounting posture of the current detector 581. It cannot be detected. If the mounting posture of the current detector 581 is incorrect, the error will affect the calculation performed by the control unit 540 (for example, the calculation of the AC power generated by the photovoltaic power generation system 520). The display unit 550 may display an incorrect calculation result. As can be understood from the above description, the technique of Patent Document 1 that detects an error in the mounting posture of the first current detector using the detection values of the two current detectors is not necessarily suitable for the distributed power generation system 500. Not not.

In view of such circumstances, the present inventor is suitable for detecting an error in the mounting posture of the current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system including the photovoltaic power generation system and the fuel cell system. Aiming to provide the technology.

That is, the first aspect of the present disclosure is
A distributed power generation system that is connected to a single-phase three-wire power system,
The distributed power generation system includes a solar power generation system, a fuel cell system, a first current detector, a first voltage specifying unit, and a control unit.
Each of the solar power generation system and the fuel cell system generates direct current power and converts the direct current power into alternating current power,
There is a single-phase three-wire first electric line connecting the electric power system and the solar power generation system,
There is a single-phase three-wire type second electric circuit that connects the fuel cell system and the first electric circuit,
Each of the first electric line and the second electric line is a combination of a ground line, a first voltage line and a second voltage line, and a first AC voltage is applied between the ground line and the first voltage line. Have a combination that is
The first voltage identifying unit identifies the first AC voltage,
The first current detector is attached to a first detection position, and specifies a current flowing through a connection point between the solar power generation system and the first voltage path of the first electric line,
When the current specified by the first current detector is defined as a first specific current and the first AC voltage specified by the first voltage specifying unit is defined as a first specific voltage, the control unit is configured to control the 1 specific current and 1st active power which is active power of the 1st specific voltage are calculated, and the 1st active power is below the 1st threshold power from the time when the 1st active power becomes below the 1st threshold power. When the state of is continued for the first threshold period, it is determined that the mounting posture of the first current detector to the first detection position is wrong,
The first threshold power is a value less than zero,
The first threshold period provides a distributed power generation system having a value of zero or more.

The technique according to the first aspect detects an error in the mounting posture of the first current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system in which the photovoltaic power generation system and the fuel cell system are combined. Especially suitable. Furthermore, according to the first aspect, it is easy to avoid a situation in which the mounting attitude is determined to be incorrect even though the mounting attitude is correct.

A second aspect of the present disclosure is, in addition to the first aspect,
When the control unit determines that the mounting posture of the first current detector is incorrect, the control unit provides a distributed power generation system that rewrites information indicating the mounting posture of the first current detector.

According to the second aspect, it is possible to prevent an error in the mounting attitude from affecting the calculation that should reflect the output current from the photovoltaic power generation system.

A third aspect of the present disclosure is, in addition to the first aspect or the second aspect,
When the control unit stores the information indicating that the mounting posture of the first current detector is incorrect, when the first numerical value is calculated using the first specific current, A distributed power generation system that handles a value obtained by multiplying a calculation result using a specific current by -1 as the first numerical value.

According to the third aspect, the first numerical value is calculated appropriately.

A fourth aspect of the present disclosure, in addition to any one of the first to third aspects,
The distributed power generation system includes a second current detector and a second voltage specifying unit,
A second AC voltage is applied between the ground path and the second voltage path in each of the first electric path and the second electric path,
The second voltage specifying unit specifies the second AC voltage,
The second current detector is attached to a second detection position, and specifies a current flowing through a connection point between the solar power generation system and the second voltage path of the first electric line,
When the current specified by the second current detector is defined as a second specified current and the second AC voltage specified by the second voltage specifying unit is defined as a second specified voltage, the control unit is configured to control the Second specific current and second active power that is active power of the second specific voltage are calculated, and the second active power is equal to or lower than the second threshold power from the time when the second active power is equal to or lower than the second threshold power. A distributed power generation system that determines that the mounting posture of the second current detector at the second detection position is incorrect when the above condition continues for the second threshold period.

The technique according to the fourth aspect detects an error in the mounting posture of the second current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system that combines the photovoltaic power generation system and the fuel cell system. Especially suitable.

A fifth aspect of the present disclosure, in addition to any one of the first to fourth aspects,
The distributed power generation system includes a display unit,
The display unit provides a distributed power generation system that displays at least one of the AC power generated by the solar power generation system and the AC power generated by the fuel cell system.

According to the fifth aspect, it is possible to easily confirm the generated AC power.

A sixth aspect of the present disclosure is any one of the first to fifth aspects,
The distributed power generation system includes a load, a first interconnection unit, and a second interconnection unit,
There is a third electrical path connecting the load and the second electrical path,
In the first interconnection part, the first electric line and the second electric line are connected,
In the second interconnection unit, the second electric line and the third electric line are connected,
In the operation mode of the distributed power generation system, the fuel cell system is generated so that current does not flow in a position between the first interconnection part and the second interconnection part in the second electric path. There is provided a distributed power generation system having a mode in which the AC power is adjusted.

The technology according to the present disclosure can be preferably used when there is a mode as defined in the sixth aspect.

A seventh aspect of the present disclosure is
A distributed power generation system that is connected to a single-phase three-wire power system,
The distributed power generation system includes a solar power generation system, a fuel cell system, a first current detector, a first voltage specifying unit, and a control unit.
Each of the solar power generation system and the fuel cell system generates direct current power and converts the direct current power into alternating current power,
There is a single-phase three-wire first electric line connecting the electric power system and the solar power generation system,
There is a single-phase three-wire type second electric circuit that connects the fuel cell system and the first electric circuit,
Each of the first electric line and the second electric line is a combination of a ground line, a first voltage line and a second voltage line, and a first AC voltage is applied between the ground line and the first voltage line. Have a combination that is
The first voltage identifying unit identifies the first AC voltage,
The first current detector is attached to a first detection position, and specifies a current flowing through a connection point between the solar power generation system and the first voltage path of the first electric line,
The mounting posture of the first current detector to the first detection position includes a first forward posture and a first reverse posture,
When the current specified by the first current detector is defined as a first specified current, and the first AC voltage specified by the first voltage specifying unit is defined as a first specified voltage, the first forward attitude is The first specific current is a posture in which a period in which the first specific current is positive is overlapped with a period in which the first specific voltage is positive. It is a posture that does not overlap in the positive period,
The control unit is in a situation where the period in which the first specific current is positive and the period in which the first specific voltage is positive do not overlap using the first specific voltage and the first specific current. A distributed power generation system is provided that, when determined, determines that the mounting posture of the first current detector is not the first forward posture.

The technique according to the seventh aspect detects an error in the mounting attitude of the first current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system that combines the photovoltaic power generation system and the fuel cell system. Especially suitable.

An eighth aspect of the present disclosure is, in addition to the seventh aspect,
The control unit calculates a first active power that is an active power of the first specific current and the first specific voltage, and the first active power from a time point when the first active power becomes equal to or lower than a first threshold power. Is less than or equal to the first threshold power for a first threshold period, the period in which the first specific current is positive does not overlap with the period in which the first specific voltage is positive. Is judged,
The first threshold power is a value less than zero,
The first threshold period provides a distributed power generation system having a value of zero or more.

According to the eighth aspect, it is easy to avoid a situation where it is determined that the mounting posture is not the first forward posture even though the mounting posture is the first forward posture.

A ninth aspect of the present disclosure is, in addition to the seventh aspect or the eighth aspect,
When the controller determines that the mounting attitude of the first current detector is not the first forward attitude (determines that the mounting attitude of the first current detector is incorrect), the first current detector Provide a distributed power generation system that rewrites information indicating the mounting posture of the.

According to the ninth aspect, it is possible to prevent an error in the mounting attitude from affecting the calculation that should reflect the output current from the photovoltaic power generation system.

A tenth aspect of the present disclosure is, in addition to any one of the seventh to ninth aspects,
The control unit stores information indicating that the first current detector is mounted in the first reverse posture (information indicating that the mounting posture of the first current detector is incorrect). When calculating the first numerical value using the first specific current when the distributed electric power generation system is used, a value obtained by multiplying the calculation result using the first specific current by -1 is treated as the first numerical value. I will provide a.

According to the tenth aspect, the first numerical value is calculated appropriately.

An eleventh aspect of the present disclosure, in addition to any one of the seventh aspect to the tenth aspect,
The distributed power generation system includes a second current detector and a second voltage specifying unit,
A second AC voltage is applied between the ground path and the second voltage path in each of the first electric path and the second electric path,
The second voltage specifying unit specifies the second AC voltage,
The second current detector is attached to a second detection position, and specifies a current flowing through a connection point between the solar power generation system and the second voltage path of the first electric line,
The mounting posture of the second current detector to the second detection position includes a second forward posture and a second reverse posture,
When the current specified by the second current detector is defined as a second specified current and the second AC voltage specified by the second voltage specifying unit is defined as a second specified voltage, the second forward attitude is It is a posture in which a period in which the second specific current is positive is overlapped with a period in which the second specific voltage is positive, and the second reverse posture is a period in which the second specific voltage is It is a posture that does not overlap in the positive period,
The control unit is in a situation where the period in which the second specific current is positive and the period in which the second specific voltage is positive do not overlap using the second specific voltage and the second specific current. A distributed power generation system is provided that, when determined, determines that the mounting posture of the second current detector is not the second forward posture.

The technology according to the eleventh aspect detects an error in the mounting posture of the second current detector that specifies the output current from the photovoltaic power generation system in the distributed power generation system in which the photovoltaic power generation system and the fuel cell system are combined. Especially suitable.

A twelfth aspect of the present disclosure, in addition to any one of the seventh to eleventh aspects,
The distributed power generation system includes a display unit,
The display unit provides a distributed power generation system that displays at least one of the AC power generated by the solar power generation system and the AC power generated by the fuel cell system.

According to the twelfth aspect, it is possible to easily confirm the generated AC power.

A thirteenth aspect of the present disclosure, in addition to any one of the seventh to twelfth aspects,
The distributed power generation system includes a load, a first interconnection unit, and a second interconnection unit,
There is a third electrical path connecting the load and the second electrical path,
In the first interconnection part, the first electric line and the second electric line are connected,
In the second interconnection unit, the second electric line and the third electric line are connected,
In the operation mode of the distributed power generation system, the fuel cell system is generated so that current does not flow in a position between the first interconnection part and the second interconnection part in the second electric path. There is provided a distributed power generation system having a mode in which the AC power is adjusted.

The technology according to the present disclosure can be preferably used when there is a mode as defined in the thirteenth aspect.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. The present disclosure is not limited to the following embodiments.

FIG. 1 shows a distributed power generation system 100 according to an embodiment. The distributed power generation system 100 can be connected to a single-phase three-wire power system (commercial system) 99. The distributed power generation system 100 includes a solar power generation system 120, a fuel cell system 130, a control unit 140, a display unit 150, a distribution board 160, a load 170, a first current detector 181, and a second current detector 181. It has a current detector 182, a first voltage specifying unit 185, and a second voltage specifying unit 186.

Each of the solar power generation system 120 and the fuel cell system 130 generates DC power and converts the DC power into AC power.

Specifically, the solar power generation system 120 includes a power generator 121 and a power conditioner 122. The generator 121 is a solar panel. The generator 121 generates DC power. The power conditioner 122 converts this DC power into AC power.

Further, the fuel cell system 130 has a generator 131 and a power conditioner 132. The generator 131 is a fuel cell. The generator 131 generates DC power. The power conditioner 132 converts this DC power into AC power.

The distribution board 160 includes a first interconnection unit 161, a second interconnection unit 162, and a third interconnection unit 163. The first interconnection unit 161 can block the flow of current through the first interconnection unit 161. The second interconnection unit 162 can block the flow of current through the second interconnection unit 162. The third interconnection unit 163 can block the flow of current through the third interconnection unit 163.

In the present embodiment, the first interconnection unit 161 is a solar cell branch breaker (PV branch breaker). Therefore, hereinafter, the first interconnection unit 161 may be referred to as a PV branch breaker 161. In the present embodiment, the second interconnection unit 162 is a main breaker. For this reason, below, the 2nd interconnection part 162 may be described as the master breaker 162. In the present embodiment, the third interconnection part 163 is a fuel cell breaker. Therefore, hereinafter, the third interconnection portion 163 may be referred to as the fuel cell breaker 163.

There is a single-phase three-wire first electric circuit 191 that connects the electric power system 99 and the solar power generation system 120. There is a single-phase three-wire type second electric line 192 that connects the fuel cell system 130 and the first electric line 191. There is a third circuit 193 connecting the load 170 and the second circuit 192. In the PV branch breaker 161, the first electric line 191 and the second electric line 192 are connected. In the main breaker 162, the second electric line 192 and the third electric line 193 are connected. Each of the first electric line 191 and the second electric line 192 has a combination of a ground line, a first voltage line, and a second voltage line. A first AC voltage is applied between the ground path and the first voltage path. A second AC voltage is applied between the ground path and the second voltage path.

The first voltage identification unit 185 identifies the first AC voltage. The second voltage identifying unit 186 identifies the second AC voltage. Below, the 1st alternating voltage specified by the 1st voltage specific part 185 may be called the 1st specific voltage. Further, the second AC voltage specified by the second voltage specifying unit 186 may be referred to as a second specified voltage.

In the example of FIG. 1, the first voltage specifying unit 185 and the second voltage specifying unit 186 are voltage detectors and are attached to the second electric circuit 192 at a position between the fuel cell system 130 and the distribution board 160. There is. A known voltage detector can be used as the voltage detector attachable at this position.

The first voltage specifying unit 185 and the second voltage specifying unit 186 may be included in the fuel cell system 130. When the first voltage specifying unit 185 and the second voltage specifying unit 186 are included in the fuel cell system 130, the first voltage specifying unit 185 and the second voltage specifying unit 186 according to an example determine the voltages as follows. Identify. That is, first, the converted voltage value is obtained by using the resistance voltage division. Next, the obtained voltage value is changed into a digital value by using an AD (Analog to Digital) converter. Next, this digital value is converted into a value of the assumed first/second AC voltage (physical quantity conversion) using a microcomputer.

In addition, the positions of the first voltage specifying unit 185 and the second voltage specifying unit 186 may be positions on the first electric path 191 or positions in the distribution board 160. In some cases it may be possible to mount the voltage detectors described above at these locations. In short, the first voltage specifying unit 185 may be any unit that can specify the first AC voltage, and the second voltage specifying unit 186 can be any unit that can specify the second AC voltage.

The first current detector 181 is attached to the first detection position. The first current detector 181 identifies the current flowing through the connection point between the photovoltaic power generation system 120 and the first voltage path of the first electric path 191. The second current detector 182 is attached to the second detection position. The second current detector 182 identifies the current flowing through the connection point between the solar power generation system 120 and the second voltage path of the first electric path 191. It should be noted that “specifying the current flowing through the connection point” is not an expression that refers only to a mode in which a current detector is provided at the connection point. “Specifying the current flowing through the connection point” means obtaining information on the current flowing through the connection point at the connection point or at another position. For example, in this example, the current flowing through the position between the solar power generation system 120 and the PV branch breaker 161 in the first electric circuit 191 is the same as the current flowing through the connection point. Therefore, information on the current flowing through the connection point can be obtained at this position. Hereinafter, the current specified by the first current detector 181 may be referred to as a first specified current. Further, the current specified by the second current detector 182 may be referred to as a second specified current.

The first current detector 181 and the second current detector 182 are detectors capable of detecting the magnitude of the current and the positive/negative directions of the current. In the present embodiment, the first current detector 181 and the second current detector 182 are current transformers. However, the first current detector 181 and the second current detector 182 may be other types of current detectors.

In the present embodiment, the first detection position and the second detection position are positions in the first electric path 191 between the solar power generation system 120 and the PV branch breaker 161. However, the first detection position and the second detection position may be positions inside the photovoltaic power generation system 120 or positions inside the PV branch breaker 161.

The mounting posture of the first current detector 181 at the first detection position includes a first forward posture and a first reverse posture. The first forward attitude is an attitude in which the period in which the first specific current is positive overlaps with the period in which the first specific voltage is positive. This definition is based on the case where electric power is output from the solar power generation system 121 to the first electric path 191 (the same applies to the first reverse posture, the second forward posture, and the second reverse posture). The first reverse posture is a posture in which the period in which the first specific current is positive is not overlapped with the period in which the first specific voltage is positive. “Overlapping the period in which the first specific current is positive with the period in which the first specific voltage is positive” is an expression indicating that the mounting posture of the first current detector 181 is correct, and the phase of the first specific current is And the phase of the first specific voltage are not completely the same. That is, if the power factor of the electric power flowing through the first detection position is 1, the attitude of “overlapping the period in which the first specific current is positive with the period in which the first specific voltage is positive” is equal to that of the first specific current. It means a posture in which the difference (phase difference) between the phase and the phase of the first specific voltage is zero. However, the power factor may deviate from 1 by an amount corresponding to an error. In such a situation, the attitude of “overlapping the period in which the first specific current is positive with the period in which the first specific voltage is positive” is a posture in which the phase difference is shifted from zero by a value corresponding to an error. Will be pointed out. As will be described later, “a period in which the first specific current is positive is overlapped with a period in which the first specific voltage is negative”, “a period in which the second specific current is positive is overlapped with a period in which the second specific voltage is positive”. The same applies to "and the period in which the second specific current is positive overlaps with the period in which the second specific voltage is negative".

In the present embodiment, the first reverse posture is a posture in which the period in which the first specific current is positive overlaps with the period in which the first specific voltage is negative. “Overlapping the period in which the first specific current is positive with the period in which the first specific voltage is negative” is an expression indicating that the mounting posture of the first current detector 181 is incorrect, and the first specific current It is not an expression that represents only that the difference between the phase (1) and the phase of the first specific voltage (phase difference) is exactly 180 degrees. As can be understood from the above description, the attitude of “overlapping the period in which the first specific current is positive with the period in which the first specific voltage is negative” shifts the above phase difference from 180 degrees by the error phase. It may also refer to a posture with a different value.

The mounting posture of the second current detector 182 at the second detection position includes a second forward posture and a second reverse posture. The second forward attitude is an attitude in which the period in which the second specific current is positive overlaps with the period in which the second specific voltage is positive. The second reverse posture is a posture in which the period in which the second specific current is positive is not overlapped with the period in which the second specific voltage is positive. "Overlapping the period in which the second specific current is positive with the period in which the second specific voltage is positive" is an expression indicating that the mounting posture of the second current detector 182 is correct, and the phase of the second specific current is And the phase of the second specific voltage completely match and the phase difference between them is zero. As can be understood from the above description, the attitude of “overlapping the period in which the second specific current is positive with the period in which the second specific voltage is positive” shifts the above phase difference from zero by the error phase. It may also refer to the attitude of making it a value.

In the present embodiment, the second reverse posture is a posture in which the period in which the second specific current is positive overlaps with the period in which the second specific voltage is negative. “Overlapping the period in which the second specific current is positive with the period in which the second specific voltage is negative” is an expression indicating that the mounting posture of the second current detector 182 is incorrect. It is not an expression that represents only that the difference between the phase of (1) and the phase of the second specific voltage (phase difference) is exactly 180 degrees. As can be understood from the above description, the attitude of “overlapping the period in which the second specific current is positive with the period in which the second specific voltage is negative” deviates the phase difference from 180 degrees by the error phase. It may also refer to a posture with a different value.

In the present embodiment, the first reverse posture is a posture that is opposite to the first forward posture. The second reverse posture is a posture opposite to the second forward posture.

Examples of the load 170 include household appliances such as a refrigerator, an air conditioner, and a television.

As shown in FIG. 2, the control unit 140 includes a voltage value acquisition unit 141, a current value acquisition unit 142, an active power calculation unit 143, a current transformer polarity determination unit (CT polarity determination unit) 144, and a current transformer polarity. The storage unit (CT polarity storage unit) 145, the current transformer polarity correction unit (CT polarity correction unit) 146, and the communication unit 147 are included. In the example of FIG. 2, the control unit 140 is independent of the solar power generation system 120 and the fuel cell system 130, but may be integrated with the solar power generation system 120 or integrated with the fuel cell system 130. It may be converted.

Hereinafter, operations of the voltage value acquisition unit 141, the current value acquisition unit 142, the active power calculation unit 143, the CT polarity determination unit 144, the CT polarity storage unit 145, and the CT polarity correction unit 146 will be described with reference to FIGS. ..

The flow of steps S201 to S205 shown in FIG. 3 is repeated every predetermined period T ₁ . The predetermined period T ₁ is 50 μs in one specific example.

In the flow of FIG. 3, first, in step S201, the voltage value acquisition unit 141 acquires the voltage value. Specifically, the voltage value acquisition unit 141 acquires the value of the first AC voltage (first specified voltage) specified by the first voltage specification unit 185. Further, the voltage value acquisition unit 141 acquires the value of the second AC voltage (second specified voltage) specified by the second voltage specifying unit 186.

Next, in step S202, the current value acquisition unit 142 acquires a current value. Specifically, the current value acquisition unit 142 acquires the current value (first specific current) detected by the first current detector 181. Further, the current value acquisition unit 142 acquires the current value (second specific current) detected by the second current detector 182. Note that step S202 may be performed before step S201.

By the way, in a discrete system, active power can be calculated as shown in FIG. In FIG. 5, “Voltage” is an AC voltage. “Current” is an alternating current. The period from time 1 to time N is a period corresponding to one cycle of the AC voltage. At time 1, time 2, time 3,... Time N, the product of the instantaneous value of the AC voltage and the instantaneous value of the AC current is calculated. The active power is obtained by dividing the integrated value of the obtained N products by N.

Step S203 subsequent to step S202 is a step in which the contents of the explanation given using FIG. 5 are reflected. That is, in step S203, the active power calculation unit 143 calculates active power. Specifically, the active power calculation unit 143 calculates the product (first product) of the first specific current and the first specific voltage. The active power calculation unit 143 calculates the first product calculated in step S203 this time, the first product calculated in step S203 one time before, and the first product calculated in step S203 two times before. The first product calculated in step S203 three times before is integrated with the first product calculated in step S203 N-1 times before. Then, the active power calculation unit 143 divides the obtained integrated value (that is, the integrated value of the N first products counting from the newest one) by N. As a result, the first effective power is obtained. The active power calculation unit 143 also calculates the product (second product) of the second specific current and the second specific voltage. The active power calculation unit 143 calculates the second product calculated in step S203 this time, the second product calculated in step S203 one time before, and the second product calculated in step S203 two times before, The second product calculated in step S203 three times before is integrated with the second product calculated in step S203 three times before N-1 times. Then, the active power calculation unit 143 divides the obtained integrated value (that is, the integrated value of the N second products counting from the newest one) by N. As a result, the second active power is obtained. N is a positive number. When the cycle of the first AC voltage (second AC voltage) is T ₂ , N is given by T ₂ /T ₁ .

Next, in step S204, the CT polarity correction unit 146 stores the phase information of the first current detector 181 (first phase information) and the phase information of the second current detector 182 (second phase information) in CT polarity storage. It is read from the unit 145 and given to the active power calculation unit 143. In this embodiment, the first phase information is “positive” or “negative”. The initial value of the first phase information is “positive”. The first phase information being “positive” means that the mounting posture of the first current detector 181 is the first forward posture (that is, the mounting posture is correct). The first phase information being “negative” means that the mounting posture of the first current detector 181 is the first reverse posture (that is, the mounting posture is incorrect). In this embodiment, the second phase information is “positive” or “negative”. The initial value of the second phase information is “positive”. The second phase information being “positive” means that the mounting posture of the second current detector 182 is the second forward posture (that is, the mounting posture is correct). The fact that the second phase information is “negative” means that the mounting posture of the second current detector 182 is the second reverse posture (that is, the mounting posture is incorrect). Note that how the first phase information and the second phase information are changed will be described later.

Next, in step S205, the active power calculation unit 143 obtains the first true active power by correcting the first active power as necessary. Moreover, the active power calculation unit 143 obtains the second true active power by correcting the second active power as necessary. Specifically, if the first phase information is “positive”, the active power calculation unit 143 treats the first active power as the first true active power. If the first phase information is “negative”, the active power calculation unit 143 treats a value obtained by multiplying the first active power by −1 as the first true active power. If the second phase information is “positive”, the active power calculation unit 143 treats the second active power as the second true active power. If the second phase information is “negative”, the active power calculation unit 143 treats a value obtained by multiplying the second active power by −1 as the second true active power.

After that, the active power calculation unit 143 obtains the AC power generated by the solar power generation system 120 by adding the first true active power and the second true active power. This AC power information is transmitted from the active power calculation unit 143 to the communication unit 147 and from the communication unit 147 to the display unit 150. In this way, it becomes possible to display the AC power on the display unit 150. Note that the second current detector 182 can be omitted, following the example of FIG. In that case, the AC power can be estimated to be twice the first true active power. If the first current detector 181 is omitted, the AC power can be estimated to be twice the second true active power. However, it is more accurate to calculate the AC power by providing both the first current detector 181 and the second current detector 182 and summing the first true active power and the second true active power. You can

FIG. 4 is a flow chart for explaining how the first phase information and the second phase information are changed from “positive” to “negative”. The flow of steps S301 to S305 shown in FIG. 4 is repeated every predetermined period T ₃ . In this embodiment, the predetermined period T ₃ is longer than the predetermined period T ₁ . The predetermined period T ₃ is 100 ms in one specific example.

First, the change of the first phase information will be described.

In step S301 of FIG. 4, the CT polarity determination unit 144 determines whether the first active power (not the first true active power) is less than or equal to the first threshold power. In the present embodiment, the first threshold power is a value smaller than zero. When the first active power is larger than the first threshold power, the count of the determination timer described later is cleared (step S302), and this flow ends. If the first active power is less than or equal to the first threshold power, the process proceeds to step S303.

In step S303, the CT polarity determination unit 144 counts up the determination timer of the CT polarity determination unit 144.

In step S304, the CT polarity determination unit 144 determines whether the count time of the determination timer is equal to or longer than the first threshold period. That is, it is determined whether the state in which the first active power is equal to or lower than the first threshold power continues for the first threshold period. In this embodiment, the first threshold period has a value of zero or more. If the count time is smaller than the first threshold period, this flow ends. If the count time is equal to or longer than the first threshold period, the process proceeds to step S305. The process proceeds to step S305 in which the control unit 140 determines that the period in which the first specific current is positive (despite the power being output from the solar power generation system 121 to the first electrical path 191) and the first specific voltage are This corresponds to determining that the positive period does not overlap.

In step S305, the CT polarity determination unit 144 determines that the mounting posture of the first current detector 181 is the first reverse posture. Then, the first phase information stored in the CT polarity storage unit 145 is inverted from “positive” to “negative”.

The second phase information can also be changed from "positive" to "negative" based on the flow of FIG.

That is, in step S301 of FIG. 4, the CT polarity determination unit 144 determines whether the second active power (not the second true active power) is less than or equal to the second threshold power. In the present embodiment, the second threshold power is a value smaller than zero. If the second active power is larger than the second threshold power, the count of the determination timer is cleared (step S302), and the current flow ends. If the second active power is less than or equal to the second threshold power, the process proceeds to step S303.

In step S303, the CT polarity determination unit 144 increments the determination timer.

In step S304, the CT polarity determination unit 144 determines whether the count time of the determination timer is the second threshold period or longer. That is, it is determined whether or not the state in which the second active power is the second threshold power or less continues for the second threshold period. In the present embodiment, the second threshold period has a value of zero or more. If the count time is smaller than the second threshold period, this flow ends. If the count time is equal to or longer than the second threshold period, the process proceeds to step S305. The process proceeds to step S305 in which the control unit 140 determines that the period in which the second specific current is positive (despite the power being output from the solar power generation system 121 to the first electrical path 191) and the second specific voltage are This corresponds to determining that the positive period does not overlap.

In step S305, the CT polarity determination unit 144 determines that the mounting posture of the second current detector 182 is the second reverse posture. Then, the second phase information stored in the CT polarity storage unit 145 is inverted from “positive” to “negative”.

As will be understood from the above description, in the present embodiment, the control unit 140 calculates the first active power that is the active power of the first specific current and the first specific voltage, and the first active power is the first threshold value. When the state in which the first active power is equal to or less than the first threshold power continues for the first threshold period from the time when the power becomes less than or equal to the power, the mounting posture of the first current detector 181 to the first detection position is incorrect. judge. The first threshold power is a value smaller than zero. The first threshold period is a value of zero or more.

The fact that the first threshold power is a value smaller than zero has the following advantages. That is, when the photovoltaic power generation system 120 does not generate power, such as at night, the photovoltaic power generation system 120 becomes a load when viewed from the power system 99. That is, the electric power corresponding to the standby electric power of the solar power generation system 120 is supplied from the power system 99 to the solar power generation system 120. Therefore, even if the mounting posture of the first current detector 181 is correct (even in the first forward posture), the first active power has a value smaller than zero by the standby power. If the first threshold power is zero, it may be determined that the mounting posture is incorrect (not the first forward posture) at night, although the mounting posture is correct. However, in the present embodiment, such a situation can be avoided because the first threshold power has a value smaller than zero. The first threshold power is, for example, −0.1 W to −5.0 W, and is, for example, −0.1 W to −1.0 W, and in one specific example, is −1.0 W.

The first threshold period may be zero, but may be a value greater than zero. The value of the first threshold period being greater than zero has the following advantages. That is, even if the mounting posture is correct, the first active power may momentarily become less than or equal to the first threshold power due to disturbance of the system, measurement error, or the like. Therefore, if it is determined that the mounting posture is incorrect immediately after the first active power becomes equal to or lower than the first threshold power, it is determined that the mounting posture is incorrect even though the mounting posture is correct. There is a risk that However, if it is determined that the mounting posture of the first current detector 181 is incorrect when the state in which the first active power is equal to or lower than the first threshold power continues for a non-zero period, such a situation should be avoided. You can The first threshold period is 60 seconds in one specific example.

In addition, in the present embodiment, the control unit 140 calculates the second active power that is the active power of the second specific current and the second specific voltage, and the second active power becomes the second threshold power or less from the time when the second active power becomes equal to or less than the second threshold power. 2 When the state in which the active power is equal to or lower than the second threshold power continues for the second threshold period, it is determined that the mounting posture of the second current detector 182 at the second detection position is incorrect. The second threshold power is a value smaller than zero. The second threshold period is a value of zero or more. The second threshold power is, for example, −0.1 W to −5.0 W, and is, for example, −0.1 W to −1.0 W, and in one specific example, −1.0 W. The second threshold period may be zero or may be a value larger than zero. A specific example of the second threshold period when it is greater than zero is 60 seconds.

The technology according to the present embodiment can also be expressed as follows. That is, in the present embodiment, the control unit 140 uses the first specific voltage and the first specific current, and the period in which the first specific current is positive and the period in which the first specific voltage is positive do not overlap. When it is determined that the mounting position of the first current detector 181 is not the first forward position. In such a determination, in the distributed power generation system 100 in which the solar power generation system 120 and the fuel cell system 130 are combined, the mounting posture of the first current detector 181 that specifies the output current from the solar power generation system 120 is incorrect. Suitable for detecting.

Further, in the present embodiment, the control unit 140 uses the second specific voltage and the second specific current, and the period in which the second specific current is positive and the period in which the second specific voltage is positive do not overlap. When it is determined that the mounting position of the second current detector 182 is not the second forward position.

In the present embodiment, when the control unit 140 determines that the mounting posture of the first current detector 181 is incorrect, the control unit 140 rewrites the information indicating the mounting posture of the first current detector 181 (first phase information) (“normal”). "To "negative"). By performing such rewriting, it is possible to prevent an error in the mounting posture from affecting the calculation that should reflect the output current from the photovoltaic power generation system 120 (for example, the calculation of the generated power of the photovoltaic power generation system 120). ..

Further, in the present embodiment, when the control unit 140 determines that the mounting posture of the second current detector 182 is incorrect, the control unit 140 rewrites information (second phase information) indicating the mounting posture of the second current detector 182 ( Change from "positive" to "negative".

In the present embodiment, the control unit 140 sets the first specific current when the information indicating that the mounting posture of the first current detector 181 is incorrect (first phase information that is “negative”) is stored. When the first numerical value is calculated using this, the value obtained by multiplying the calculation result using the first specific current by -1 is treated as the first numerical value. In this way, the first numerical value is calculated appropriately. Note that, in one example, the true first active power corresponds to the first numerical value.

Further, in the present embodiment, the control unit 140 performs the second identification when storing the information indicating that the mounting posture of the second current detector 182 is incorrect (“negative” second phase information). When the second numerical value is calculated using the current, a value obtained by multiplying the calculation result using the second specific current by -1 is treated as the second numerical value. In one example, the true second active power corresponds to the second numerical value.

In the present embodiment, the display unit 150 displays at least one of the AC power generated by the solar power generation system 120 and the AC power generated by the fuel cell system 130. By doing so, the generated AC power can be easily confirmed.

When the calculated value of the AC power generated by the solar power generation system 120 is smaller than zero, the display unit 150 displays that the AC power is zero, instead of displaying the calculated value. May be. In such a case, the user can know at a glance at the display unit 150 whether or not power is being generated by the solar power generation system 120. It is possible to detect an error in the mounting posture of the first current detector 181 and the second current detector 182 when the display unit 150 is such, and there are the following advantages. That is, assume that the control unit 140 is replaced with a control unit that cannot detect an error in the mounting posture of the current detector 181 and the second current detector 182. Further, it is assumed that the mounting postures of the first current detector 181 and the second current detector 182 are incorrect (specifically, the first/second reverse posture). In that case, the display unit 150 continues to display that the AC power is zero, although the AC power is actually generated in the solar power generation system 120. A user who sees such a display may misunderstand that the solar power generation system 120 is not generating power. However, since the control unit 140 can detect an error in the mounting posture of the first current detector 181, it is possible to avoid such a misunderstanding.

In the present embodiment, in the operation mode of the distributed power generation system 100, the position between the first interconnection part (PV branch breaker) 161 and the second interconnection part (main trunk breaker) 162 in the second electric circuit 192 is set. There is a mode in which the AC power generated in the fuel cell system 130 is adjusted so that no current flows. In the case where the operation mode has such a mode, the technique of the present embodiment can be preferably used. However, the technology of the present embodiment is also applicable to a distributed power generation system that is not operated in such a mode. It should be noted that it is technically possible to adjust the AC power generated by the fuel cell system 130 so that the current does not flow in the position between the first interconnection part 161 and the second interconnection part 162 in the second electric path 192. It's not difficult. For example, following the example of FIG. 6, a current detector is attached between the first interconnection portion 161 and the second interconnection portion 162 in the first voltage passage of the second electric passage 192 and the second electric passage 192 By attaching a current detector between the first interconnection part 161 and the second interconnection part 162 of the voltage path (see current detectors 583 and 584), feedback control for the above adjustment can be performed. it can. Such feedback control may be performed by the controller 140.

99,499 Power system 100,500 Distributed power generation system 120,520 Solar power generation system 121,131,521,531 Generator 122,132,522,532 Power conditioner 130,530 Fuel cell system 140,540 Control part 141 Voltage Value acquisition unit 142 Current value acquisition unit 143 Active power calculation unit 144 Current transformer polarity determination unit (CT polarity determination unit)
145 Current transformer polarity storage unit (CT polarity storage unit)
146 Current transformer polarity correction unit (CT polarity correction unit)
147 Communication unit 150,550 Display unit 160,560 Distribution board 161,162,163 Connection unit (breaker)
170,570 Load 181,182,581,583,584 Current detector 185,186,585,586 Voltage specifying part 191,192,193,591,592,593 Electric circuit 561,562,563 Breaker

Claims (7)

A distributed power generation system that is connected to a single-phase three-wire power system,
The distributed power generation system includes a solar power generation system, a fuel cell system, a first current detector, a first voltage specifying unit, and a control unit.
Each of the solar power generation system and the fuel cell system generates direct current power and converts the direct current power into alternating current power,
There is a single-phase three-wire first electric line connecting the electric power system and the solar power generation system,
There is a single-phase three-wire type second electric circuit that connects the fuel cell system and the first electric circuit,
Each of the first electric line and the second electric line is a combination of a ground line, a first voltage line and a second voltage line, and a first AC voltage is applied between the ground line and the first voltage line. Have a combination that is
The first voltage identifying unit identifies the first AC voltage,
The first current detector is attached to a first detection position, and specifies a current flowing through a connection point between the solar power generation system and the first voltage path of the first electric line,
When the current specified by the first current detector is defined as a first specific current and the first AC voltage specified by the first voltage specifying unit is defined as a first specific voltage, the control unit is configured to control the 1 specific current and 1st active power which is active power of the 1st specific voltage are calculated, and the 1st active power is below the 1st threshold power from the time when the 1st active power becomes below the 1st threshold power. When the state of is continued for the first threshold period, it is determined that the mounting posture of the first current detector to the first detection position is wrong,
The first threshold power is -0.1W to -5.0W ,
The distributed power generation system, wherein the first threshold period has a value of zero or more. The distributed power generation system according to claim 1, wherein the control unit rewrites the information indicating the mounting posture of the first current detector when determining that the mounting posture of the first current detector is incorrect. Wherein, in case that stores information indicating that the incorrect mounting orientation of the first current detector, a first active power true by Rukoto multiplied by -1 in the first active power The distributed power generation system according to claim 1 or 2, which is obtained . The distributed power generation system includes a second current detector and a second voltage specifying unit,
A second AC voltage is applied between the ground path and the second voltage path in each of the first electric path and the second electric path,
The second voltage specifying unit specifies the second AC voltage,
The second current detector is attached to a second detection position, and specifies a current flowing through a connection point between the solar power generation system and the second voltage path of the first electric line,
When the current specified by the second current detector is defined as a second specified current and the second AC voltage specified by the second voltage specifying unit is defined as a second specified voltage, the control unit is configured to control the Second specific current and second active power that is active power of the second specific voltage are calculated, and the second active power is equal to or lower than the second threshold power from the time when the second active power is equal to or lower than the second threshold power. When the above condition continues for the second threshold period, it is determined that the mounting posture of the second current detector to the second detection position is wrong ,
The second threshold power is -0.1W to -5.0W,
The distributed power generation system according to claim 1, wherein the second threshold period has a value of zero or more . The distributed power generation system includes a display unit,
The dispersion according to claim 1, wherein the display unit displays at least one of the AC power generated by the solar power generation system and the AC power generated by the fuel cell system. Type power generation system. The distributed power generation system includes a load, a first interconnection unit, and a second interconnection unit,
There is a third electrical path connecting the load and the second electrical path,
In the first interconnection part, the first electric line and the second electric line are connected,
In the second interconnection unit, the second electric line and the third electric line are connected,
In the operation mode of the distributed power generation system, the fuel cell system is generated so that current does not flow in a position between the first interconnection part and the second interconnection part in the second electric path. The distributed power generation system according to claim 1, wherein there is a mode in which the AC power is adjusted. A distributed power generation system that is connected to a single-phase three-wire power system,
The distributed power generation system includes a solar power generation system, a fuel cell system, a first current detector, a first voltage specifying unit, and a control unit.
Each of the solar power generation system and the fuel cell system generates direct current power and converts the direct current power into alternating current power,
There is a single-phase three-wire first electric line connecting the electric power system and the solar power generation system,
There is a single-phase three-wire type second electric circuit that connects the fuel cell system and the first electric circuit,
Each of the first electric line and the second electric line is a combination of a ground line, a first voltage line and a second voltage line, and a first AC voltage is applied between the ground line and the first voltage line. Have a combination that is
The first voltage identifying unit identifies the first AC voltage,
The first current detector is attached to a first detection position, and specifies a current flowing through a connection point between the solar power generation system and the first voltage path of the first electric line,
The mounting posture of the first current detector to the first detection position includes a first forward posture and a first reverse posture,
When the current specified by the first current detector is defined as a first specified current, and the first AC voltage specified by the first voltage specifying unit is defined as a first specified voltage, the first forward attitude is The first specific current is a posture in which a period in which the first specific current is positive is overlapped with a period in which the first specific voltage is positive, and the first reverse posture is a period in which the first specific voltage is positive during the period in which the first specific current is positive. It is a posture that does not overlap in the positive period,
The control unit uses the first specific voltage and the first specific current, the period in which the first specific current is positive and the period in which the first specific voltage is positive do not overlap, and the sun When it is determined that active power whose absolute value is larger than that flowing due to standby power of the photovoltaic system is flowing through the connection point , the mounting posture of the first current detector is the first position. A distributed power generation system that determines that the attitude is not normal.

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