JP2017181466A - Cogeneration system and cogeneration system sensor check method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily determine an attachment position of a current sensor in a cogeneration system.SOLUTION: A cogeneration system S comprises: a CT1 sensor 41 and a CT2 sensor 42 that are attached to any of U, N and V phases constituting a three-phase AC to be connected to an internal-household load 6 with any direction thereof, respectively; a U phase load 31u that is capable of energization between U-N phases; a V phase load 31v that is capable of energization between V-N phases; and a PCS1 that determines presence or absence of the energization and energization direction due to the U phase load 31u from a deviation between measurement results of the CT1 sensor 41 upon energization/non-energization of the U phase load 31u and the CT2 sensor 42 thereupon, determines presence or absence of the energization and energization direction due to the V phase load 31v from a deviation between measurement results of the CT1 sensor 41 upon energization/non-energization of the V phase load 31v and the CT2 sensor 42 thereupon, and determines an attachment line and direction of the CT1 sensor 41 and the CT2 sensor 42.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cogeneration system and a cogeneration system sensor check method, and more particularly to a cogeneration system and a cogeneration system sensor check method suitable for determining a connection of a CT (Current Transformer) sensor of the cogeneration system. About.

  When installing a cogeneration system in a power supply system that sends power from a system power supply to a household load via a distribution line, the output side of the power supply of this cogeneration system is connected to a grid connection inverter and a grid connection distribution line. It is electrically connected to the distribution line. In home cogeneration systems, reverse power flow to the system of generated power is not allowed. Therefore, it is necessary to attach a CT sensor (current sensor) to the switchboard and monitor the current.

  At that time, it is necessary to attach the two CT sensors in the correct wiring and the correct orientation, but there are 6 types of mounting variations in the U-phase, N-phase, and V-phase 3 wires x 2 directions. It is necessary to verify the set.

  On the other hand, the technique of patent document 1 is proposed. The means for solving the abstract of Patent Document 1 includes “the generator 4 for cogeneration and the power from the generator 4 to the commercial distribution line 16 from the commercial power supply 14 via the distribution line 22 for grid connection. The grid interconnection inverter 12 for interconnection, the current detector 86 for detecting the current flowing through the commercial distribution line 16, and the grid interconnection inverter 12 from the generator 4 using the detection current of the current detector 86 System control means 72 for controlling the power supplied to the commercial distribution line 16 via the grid connection distribution line 22, and the system control means 72 has stopped the operation of the generator 4. In the state, the connection state of the current detector 86 is diagnosed based on the detection current of the current detector 86. "

JP 2002-286785 A

In the technique described in Patent Document 1, when the current is detected by the current detector, the operation of the generator is stopped. However, in a home cogeneration system, it is extremely complicated to stop all loads in the home.
Moreover, since the technique described in Patent Document 1 requires a dedicated power load, the number of parts and the cost may increase.

  This invention is made in view of such a situation, and makes it a subject to provide the sensor check method of a cogeneration system and a cogeneration system which can determine the attachment position of a current sensor easily.

The invention according to claim 1 is a cogeneration system,
A first current sensor and a second current sensor respectively attached to any one of U, N, and V phases constituting a three-phase alternating current connected to a home load;
A U-phase load that can be energized between the U-N phases of the three-phase alternating current;
A V-phase load that can be energized between V-N phases of the three-phase alternating current;
The measurement results of the first and second current sensors when the U-phase load is not energized and the measurement results of the first and second current sensors when the U-phase load is energized From the deviation, it is determined whether or not the first and second current sensors are energized by the U-phase load and the energization direction, and the first and second currents when the V-phase load is not energized. Energization of each of the first and second current sensors by the V-phase load is based on a deviation between the measurement result of the sensor and the measurement results of the first and second current sensors when the V-phase load is energized. A determination unit that determines the presence / absence and the energization direction of the first and second current sensors, and determines the attachment line and direction of each of the first and second current sensors;
Is provided.
According to the present invention, it is possible to easily determine the mounting position of the current sensor.

According to a second aspect of the present invention, in the cogeneration system according to the first aspect, the determination unit uses random numbers for energization time and energization timing of the U-phase load and the V-phase load.
According to the present invention, it is possible to easily determine the mounting position of the current sensor without stopping the household load or the like.

According to a third aspect of the present invention, in the cogeneration system according to the first or second aspect, if the determination unit is a combination in which the attachment lines and directions of the first and second current sensors are not acceptable, an error occurs. Is to be notified.
According to the present invention, in addition to the function and effect of the first or second aspect of the invention, it is possible to immediately determine when the first and second current sensors are mounted in an unacceptable mounting line and orientation. It becomes.

According to a fourth aspect of the present invention, in the cogeneration system according to any one of the first to third aspects, the U-phase load and the V-phase load are glow heaters used in the cogeneration system. Is.
According to this invention, in addition to the operation and effect of the invention described in any one of claims 1 to 3, it is possible to determine the mounting position of the current sensor without any additional parts.

The invention described in claim 5
A first current sensor and a second current sensor respectively attached to any one of U, N, and V phases constituting a three-phase alternating current connected to a home load;
A U-phase load that can be energized between the U-N phases of the three-phase alternating current;
A V-phase load that can be energized between V-N phases of the three-phase alternating current;
A determination unit;
In the sensor check method executed by the cogeneration system equipped with
Measure the current with each of the first and second current sensors when the U-phase load is not energized,
Current is measured by each of the first and second current sensors when the U-phase load is energized,
Determining whether or not the first and second current sensors are energized by the U-phase load and the energization direction;
The current is measured by each of the first and second current sensors when the V-phase load is not energized,
Current is measured by each of the first and second current sensors when the V-phase load is energized,
The presence / absence of energization by the V-phase load and the energization direction of each of the first and second current sensors are determined, and the attachment lines and directions of the first and second current sensors are determined. .
According to the present invention, it is possible to easily determine the mounting position of the current sensor.

  ADVANTAGE OF THE INVENTION According to this invention, the sensor check method of a cogeneration system and a cogeneration system which can determine the attachment position of an electric current sensor easily can be provided.

It is a block diagram of the fuel cell cogeneration system of this embodiment. It is a figure which shows the attachment state of CT sensor. It is a figure which shows the combination of the attachment state of allowable CT sensor. It is a timing chart for calculation of 2 electric power and determination of a direction. It is a sequence diagram which shows the operation | movement at the time of normal between units of ECU-PCS. It is a sequence diagram which shows the operation | movement at the time of the abnormality detection between units of ECU-PCS. It is a flowchart which shows a U-phase load test | inspection (the 1). It is a flowchart which shows a U-phase load test | inspection (the 2). It is a flowchart which shows a V-phase load test | inspection (the 1). It is a flowchart which shows a V-phase load test | inspection (the 2). It is a flowchart which shows a V-phase load test | inspection (the 3). It is a flowchart which shows a V-phase load test | inspection (the 4).

Embodiments of the present invention will be described below with reference to the accompanying drawings.
Note that each element in the drawings may be appropriately enlarged, reduced, or simplified in order to facilitate understanding of the invention.

FIG. 1 is a configuration diagram of a cogeneration system S of the present embodiment.
As shown in FIG. 1, the cogeneration system S of the present embodiment includes a PCS (Power Conditioning System) 1, an ECU (Electronic Control Device) 2, an auxiliary machine 3, a CT1 sensor 41, and a CT2 sensor 42. The system power supply 9 is connected to the U-phase wiring 91, the V-phase wiring 92, and the N-phase wiring 93. This system power supply 9 is also connected to the household load 6 in parallel with the cogeneration system S.

  The PCS 1 controls the ECU 2 so that the power generated by the auxiliary machine 3 that is a fuel cell does not flow backward to the system power supply 9. Further, the PCS 1 outputs reactive power so that the driving power factor is constant with respect to the output of the auxiliary machine 3 that is a fuel cell, for example, and the voltage fluctuations of the U-phase wiring 91, the V-phase wiring 92, and the N-phase wiring 93. Suppress. Furthermore, the PCS 1 operates as a determination unit that determines the attachment lines and orientations of the CT1 sensor 41 and the CT2 sensor 42.

The auxiliary machine 3 is a fuel cell main body, and includes a U-phase load 31u and a V-phase load 31v that are glow heaters used in the fuel cell. The U-phase load 31u can be energized between the U and N phases, and the V-phase load 31v can be energized between the V and N phases. In the present embodiment, the mounting lines and directions of the CT1 sensor 41 and the CT2 sensor 42 are determined by the U-phase load 31u and the V-phase load 31v, which are glow heaters of the fuel cell. Judgment is possible.
The ECU 2 is an electronic control unit that controls the auxiliary machine 3. For example, the U-phase load 31u is turned on / off to switch between energization and de-energization, and the V-phase load 31v is turned on / off to energize and de-energize. Switch.

  The CT1 sensor 41 is a first current sensor and is connected to the PCS1. In FIG. 1, a CT1 sensor 41 is a current transformer, and measures a U-phase current with a positive power flow flowing from the system power supply 9. The position of the CT1 sensor 41 at this time is referred to as position # 2. In addition, when the CT1 sensor 41 and the CT2 sensor 42 are connected to a position where a U-phase current with the reverse power flow direction to the system power supply 9 is measured, this is referred to as position # 1.

  The CT2 sensor 42 is a second current sensor and is connected to the PCS1. In FIG. 1, a CT2 sensor 42 is a current transformer, and measures a V-phase current in which the power flow flowing from the system power supply 9 is positive. The position of the CT2 sensor 42 at this time is referred to as position # 4. Further, when the CT1 sensor 41 and the CT2 sensor 42 are connected to a position where a U-phase current with the reverse power flow direction to the system power supply 9 as a positive direction is measured, this is referred to as a position # 3.

  When the CT1 sensor 41 and the CT2 sensor 42 are connected to a position where an N-phase current with a positive power flow flowing from the system power supply 9 is measured, this is referred to as position # 6. Further, when the CT1 sensor 41 and the CT2 sensor 42 are connected to a position where an N-phase current with the reverse power flow direction to the system power supply 9 as a positive direction is measured, this is referred to as a position # 5.

  The purpose of the CT direction correction performed during the test run after the system is installed is to check whether the CT1 sensor 41 and the CT2 sensor 42 are properly installed and to internally correct the mounting positions and directions of the CT1 sensor 41 and the CT2 sensor 42. is there. In performing the CT direction correction, it is necessary to coordinate the operation between the ECU 2 and the PCS 1. The processing outline is shown below.

  Initially, a request for CT direction correction is transmitted from the ECU 2 to the PCS 1 by inter-unit communication (hereinafter referred to as CAN communication). When the PCS 1 receives the request for the CT direction correction, the PCS 1 requests the ECU 2 to turn on / off the load device for each phase, and the current value detected from the CT 1 sensor 41 and the CT 2 sensor 42 and the power of each phase from the system voltage value. Perform the operation. This process will be described in detail with reference to FIG.

If it is determined that the CT attachment state is normal as a result of the power calculation of each phase, the PCS 1 stores the attachment location and direction. Further, if the CT mounting state is not determined to be normal, the PCS 1 determines that the wiring is incorrect. This process will be described with reference to the flowcharts of FIGS.
The PCS 1 determines the result of the CT direction correction and transmits it to the ECU 2. The ECU 2 cancels the request for performing the CT direction correction based on the determination result in the PCS 1 and performs the corresponding next process.

FIG. 2 is a view showing a state in which the CT sensor is attached.
The CT attachment state shown in FIG. 2 corresponds to the positions # 1 to # 6 shown in FIG.
When the CT attachment state is position # 1, the attachment phase of the CT1 sensor 41 and the CT2 sensor 42 is the U phase, and the current direction during power calculation is negative. When the CT attachment state is position # 2, the attachment phase of the CT1 sensor 41 and the CT2 sensor 42 is the U phase, and the current direction during power calculation is positive.

When the CT attachment state is position # 3, the attachment phase of the CT1 sensor 41 and the CT2 sensor 42 is the V phase, and the current direction during power calculation is negative. When the CT mounting state is position # 4, the mounting phase of the CT1 sensor 41 and the CT2 sensor 42 is the V phase, and the current direction during power calculation is positive.
When the CT attachment state is position # 5, the attachment phase of the CT1 sensor 41 and the CT2 sensor 42 is the N phase, and the current direction during power calculation is negative. When the CT attachment state is position # 6, the attachment phase of the CT1 sensor 41 and CT2 sensor 42 is the N phase, and the current direction during power calculation is positive.

  When the CT attachment state is other, the attachment phase of the CT1 sensor 41 or the CT2 sensor 42 is not any of the U phase, V phase, and N phase, and the current direction during power calculation is neither plus or minus.

FIG. 3 is a diagram showing a combination of allowable mounting states of the CT1 sensor 41 and the CT2 sensor 42.
The states are described in order from alphabets starting with A to H, and indicate combinations of respective attachment states.
When in state A, the attachment state of the CT1 sensor 41 is position # 2, and the attachment state of the CT2 sensor 42 is position # 4. This state A is an initial value and is assumed to be attached in this way. In a state where the CT direction correction is not completed, the PCS 1 stores the CT1 sensor 41 as the position # 2 and the CT2 sensor 42 as the position # 4 as initial values. When the CT position detected by the CT direction correction can be determined as an acceptable combination as the CT mounting position, the detected CT position is stored. In addition to the state A, acceptable combinations are listed in the following states B to H.

In the state B, the attachment state of the CT1 sensor 41 is the position # 2, and the attachment state of the CT2 sensor 42 is the position # 3.
In the state C, the attachment state of the CT1 sensor 41 is the position # 1, and the attachment state of the CT2 sensor 42 is 4. In the state D, the attached state of the CT1 sensor 41 is position # 1, and the attached state of the CT2 sensor 42 is position # 3.

In the state E, the attachment state of the CT1 sensor 41 is 4, and the attachment state of the CT2 sensor 42 is position # 2. In the state F, the attachment state of the CT1 sensor 41 is position # 4, and the attachment state of the CT2 sensor 42 is position # 1.
In the state G, the attachment state of the CT1 sensor 41 is position # 3, and the attachment state of the CT2 sensor 42 is position # 2. In state H, the attached state of the CT1 sensor 41 is position # 3, and the attached state of the CT2 sensor 42 is position # 1.
Other combinations are not acceptable in this system. Therefore, if the combination is unacceptable as a result of the inspection, the PCS 1 determines that the wiring is incorrect and notifies the ECU 2 of it.

  After the inspection is completed, when the PCS 1 receives the CT direction correction request again from the ECU 2, the stored CT sensor position is discarded, and the CT state is corrected after returning to the initial state A. The PCS 1 performs power calculation assuming that the CT1 sensor 41 and the CT2 sensor 42 are in the initial state during the CT direction correction operation. After the attachment state of the CT1 sensor 41 and the CT2 sensor 42 is determined, the PCS 1 calculates the system power with a voltage in combination with the determined position.

FIG. 4 is a timing chart for calculating two powers and determining a direction.
These timing charts show, in order from the top, the ON request for the U-phase load 31u by the PCS1, the presence / absence of energization of the U-phase load 31u by the ECU2, the ON request for the V-phase load 31v by the PCS1, and the V-phase load 31v by the ECU2. It shows the presence or absence of energization.
Period t2 is a load OFF period.

The period t1u is a period in which the PCS1 requests to turn on the U-phase load 31u, and the period t1v is a period in which the PCS1 requests to turn on the V-phase load 31v. The periods t1u and t1v are set to a minimum of 1.0 seconds, and are randomly set to 0.1 seconds to 2.0 seconds in units of 0.1 seconds using random numbers. Further, the PCS 1 does not request to turn on the U-phase load 31u and turn on the V-phase load 31v at the same time.
The period t2 is a period for requesting the load off by the PCS1. The period t2 is set to a minimum of 1.0 seconds, and is set to a range of 1.0 seconds to 2.0 seconds in a unit of 0.1 seconds using a random number. Thus, the PCS 1 randomly determines the energization timing of the U-phase load 31u and the V-phase load 31v using random numbers. As a result, even when the household load 6 is in operation, the power for energizing the CT1 sensor 41 and the CT2 sensor 42 by turning on the U-phase load 31u while avoiding synchronization with the current flowing through the household load 6, and V It is possible to more accurately measure the electric power for energizing the CT1 sensor 41 and the CT2 sensor 42 by turning on the phase load 31v.

The period t3u is 0.5 seconds before the PCS 1 requests to turn on the U-phase load 31u. In this period t3u, the PCS 1 measures the number of cycles corresponding to 0.5 seconds by the CT1 sensor 41 and the CT2 sensor 42, and calculates the OFF power of the U-phase load 31u.
The period t4u is 0.5 seconds before the PCS1 requests the U-phase load 31u to be turned off. In this period t4u, the PCS 1 measures the current of the number of cycles corresponding to 0.5 seconds by the CT1 sensor 41 and the CT2 sensor 42, and calculates it as the ON power of the U-phase load 31u.
Next, the PCS 1 calculates the deviation between the ON power and the OFF power of the U-phase load 31u by the CT1 sensor 41 and the deviation between the ON power and the OFF power of the U-phase load 31u by the CT2 sensor 42.

The period t3v is 0.5 seconds before the PCS1 makes an ON request to the V-phase load 31v. In this period t3u, the PCS 1 measures the number of cycles corresponding to 0.5 seconds by the CT1 sensor 41 and the CT2 sensor 42, and calculates the OFF power of the V-phase load 31v.
The period t4v is 0.5 seconds before the PCS 1 makes an OFF request to the V-phase load 31v. In this period t4v, the PCS 1 measures the number of cycles corresponding to 0.5 seconds by the CT1 sensor 41 and the CT2 sensor 42, and calculates the ON power of the V-phase load 31v. Next, the PCS 1 calculates the deviation between the ON power and the OFF power of the V-phase load 31v by the CT1 sensor 41, and calculates the deviation between the ON power and the OFF power of the V-phase load 31v by the CT2 sensor 42.

  The PCS 1 repeats the calculation of the deviation between the ON power and the OFF power of the U-phase load 31u and the calculation of the deviation between the ON power and the OFF power of the V-phase load 31v by the CT1 sensor 41 and the CT2 sensor 42 a predetermined number of times. Then, the average value (U phase: Pu, V phase: Pv) of each power deviation of the U-phase load 31u and the V-phase load 31v is calculated.

  The PCS 1 determines that the CT1 sensor 41 is “energized” if the absolute value of the average value of each power deviation by the CT1 sensor 41 is equal to or greater than a specified value. When the absolute value of the average value of each power deviation by the CT1 sensor 41 is less than the specified value, it is determined that “no power supply”. The PCS 1 further determines the mounting direction of the CT1 sensor 41 based on whether the average value of each power deviation by the CT1 sensor 41 is positive or negative.

Further, the PCS 1 determines that the CT2 sensor 42 is “energized” if the absolute value of the average value of each power deviation by the CT2 sensor 42 is equal to or greater than a specified value. When the absolute value of the average value of each power deviation by the CT2 sensor 42 is less than the specified value, it is determined that “no power supply”. The PCS 1 further determines the mounting direction of the CT1 sensor 41 based on whether the average value of each power deviation by the CT1 sensor 41 is positive or negative.
Based on such determination, the PCS 1 determines and stores the attachment state of the CT1 sensor 41 and the CT2 sensor 42. If the PCS 1 cannot determine even after repeatedly performing a predetermined number of times, it determines that the wiring is incorrect and notifies the ECU 2 of an error.
Note that the PCS 1 may randomly determine the period t3u, the period t4u, the period t3v, and the period t4v using random numbers. As a result, even when the household load 6 is in operation, the power for energizing the CT1 sensor 41 and the CT2 sensor 42 by turning on the U-phase load 31u while avoiding synchronization with the current flowing through the household load 6, and V It is possible to more accurately measure the electric power for energizing the CT1 sensor 41 and the CT2 sensor 42 by turning on the phase load 31v.

FIG. 5 is a sequence diagram showing the normal operation between the units of ECU2-PCS1.
These sequence diagrams show, in order from the top, the CT direction correction execution request by the ECU 2, the CT direction correction control state, the ON / OFF of the U-phase load 31u by the ECU 2, and the ON / OFF of the V-phase load 31v. Yes. Further below that, normal completion / in-progress / request accepting / acceptance prohibition indicating the state of PCS1, the ON request for U-phase load 31u by PCS1, the ON request for V-phase load 31v, and the abnormality that PCS1 determines Is shown.

At time T0, PCS1 is in a reception-prohibited state and cannot perform CT direction correction, and therefore transmits reception prohibition information to ECU2.
At time T1, PCS1 transitions to a standby state and can perform CT direction correction, and therefore transmits acceptance information to ECU2. Thus, a CT direction correction request is set in the ECU 2.
Time T2 is the execution timing of the CT direction correction of the ECU 2. Since the request of PCS1 is being received at time T2, ECU 2 transmits a CT direction correction execution request to PCS1.
When receiving the CT direction correction execution request from the ECU 2, the PCS 1 transmits CT direction correction execution information to the ECU 2 at time T3.

After confirming that the ECU 2 is in the CT direction correction control state at time T4a, the PCS 1 transmits a load ON request and a load OFF request for each phase to the ECU 2. Thereafter, in a period T4 from time T4a to time T4f, the PCS 1 turns on / off each phase load and measures the CT1 sensor 41 and the CT2 sensor.
At time T4b, the PCS 1 transmits an ON request for the U-phase load 31u to the ECU 2. The ECU 2 turns on the U-phase load 31u and transmits the load state, and the PCS 1 measures the CT1 sensor 41 and the CT2 sensor 42.
At time T4c, the PCS 1 transmits an OFF request for the U-phase load 31u to the ECU 2. The ECU 2 turns off the U-phase load 31u and transmits the load state, and the PCS 1 measures the CT1 sensor 41 and the CT2 sensor 42.

At time T4d, the PCS 1 transmits an ON request for the V-phase load 31v to the ECU 2. The ECU 2 turns on the V-phase load 31v and transmits the load state, and the PCS 1 measures the CT1 sensor 41 and the CT2 sensor 42.
At time T4e, the PCS 1 transmits an OFF request for the V-phase load 31v to the ECU 2. The ECU 2 turns off the V-phase load 31v and transmits the load state, and the PCS 1 measures the CT1 sensor 41 and the CT2 sensor 42.
At time T4f, the PCS 1 makes a result determination based on these measurement results. In FIG. 5, since the PCS 1 determines that the result is normal, it transmits normal completion to the ECU 2 at time T5.

After receiving normal completion from PCS1 at time T5, ECU 2 clears the CT direction correction request and the CT direction correction control state.
At time T6, if the PCS 1 confirms that the CT direction correction request and the CT direction correction control state have been cleared, the PCS 1 transitions to a request accepting state.
The PCS 1 basically sets the CT direction correction execution state to the accepting state except for the processing period such as during the self-diagnosis during the standby state, and corrects the CT direction when the grid power generation state, the independent power generation, and the error occur. The implementation status is set to the acceptance prohibition status.

FIG. 6 is a sequence diagram showing an operation at the time of detecting an abnormality between both units of ECU2-PCS1.
The operations of the ECU 2 and the PCS 1 from the time T0 to the time T4e are the same as the operations at the time of normal detection shown in FIG.
At time T4f, the PCS 1 makes a result determination based on these measurement results. In FIG. 6, since the PCS 1 determines that the result is abnormal, the corresponding error information is transmitted to the ECU 2 at time T5.
At time T5, when the ECU 2 receives the CT direction correction abnormality from the PCS 1, the ECU 2 clears the CT direction correction request and the CT direction correction control state, and performs error processing.
If the PCS 1 confirms that the CT direction correction request and the CT direction correction control state have been cleared, the PCS 1 transitions to an acceptance prohibition state, and thereafter performs error processing.

FIG. 7 is a flowchart showing the U-phase load inspection (part 1).
The PCS 1 starts determining the attachment positions of the CT1 sensor 41 and the CT2 sensor 42 according to the flow shown in FIGS. The mounting positions of the CT1 sensor 41 and the CT2 sensor 42 are determined by using the U-phase load 31u and the V-phase load 31v controlled by the ECU 2, and the mounting line and the direction based on the power value recognized as the magnitude of the energization current. judge.

The PCS 1 measures the current when the U-phase load 31u is turned on and the current when the U-phase load 31u is turned on by using the CT1 sensor 41 and the CT2 sensor 42, and obtains the ON power and the OFF power of the U-phase load 31u. A deviation from the power is calculated (step S10).
When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 is equal to or less than the threshold value, the PCS 1 determines that the current flowing through the U-phase load 31u is not energizing the CT1 sensor 41 (step S11 → No). The process proceeds to step S30 in FIG.
When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 exceeds the threshold value, the PCS 1 determines that the current flowing through the U-phase load 31u has passed through the CT1 sensor 41 (step S11 → Yes), The process proceeds to step S12.

  In step S12, the PCS 1 energizes the CT1 sensor 41 and if the electric power 1 consumed by the U-phase load 31u is positive (step S12 → Yes), the state of the CT1 sensor 41 is position # 2 or position # 6. (Step S13), the process proceeds to step S14. The PCS 1 determines that the state of the CT1 sensor 41 is the position # 1 or the position # 5 if the electric power 1 consumed by the U-phase load 31u by energizing the CT1 sensor 41 is negative (step S12 → No) ( The process proceeds to step S18) and step S19.

  In step S14, the PCS 1 determines that the current flowing through the U-phase load 31u has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S14). (Yes), it is determined that the state of the CT2 sensor 42 is any one of the positions # 1, # 2, # 5, or the position # 6 (step S15). Since this is an unacceptable combination, PCS1 adds 1 to the number of repetitions (step S16), and proceeds to the error processing of step S23.

  In step S14, the PCS 1 determines that the current flowing through the U-phase load 31u is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S14). → No), it is determined that the state of the CT2 sensor 42 is any of the positions # 3, # 4 or “others” (step S17), and the process proceeds to step S40 in FIG.

  In step S19, the PCS 1 determines that the current flowing through the U-phase load 31u has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S19). (Yes), the state of the CT2 sensor 42 is determined to be one of the positions # 1, # 2, # 5, or the position # 6 (step S20). Since this is an unacceptable combination, PCS1 adds 1 to the number of repetitions (step S21), and proceeds to the error processing of step S23.

  In step S19, the PCS 1 determines that the current flowing through the U-phase load 31u is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S19). → No), it is determined that the state of the CT2 sensor 42 is at position # 3, # 4 or any other position (step S22), and the process proceeds to step S60 in FIG.

  In the error processing of step S23, if the number of repetitions does not exceed the predetermined number (step S23 → No), the PCS 1 performs the U-phase load inspection again in step S10, and the number of repetitions exceeds the threshold value. If so (step S23 → Yes), it is determined that the wiring is incorrect (step S24), and the CT direction correction processing is abnormally terminated.

  In the load inspection, the detection result may change depending on the operation state of the household load 6. Therefore, even if the PCS 1 has an unacceptable combination result, the confirmation operation of the CT attachment direction is performed a predetermined number of times determined by the number of times of inspection. When the load inspection is repeated a predetermined number of times and the combination is not acceptable, the PCS 1 performs erroneous wiring determination and notifies the ECU 2.

FIG. 8 is a flowchart showing the U-phase load inspection (part 2).
In step S30, the PCS 1 determines that the state of the CT1 sensor 41 is any of the positions # 3, # 4, or “others”.

  In step S31, the PCS 1 determines that the current flowing through the U-phase load 31u is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S31). → No), the state of the CT2 sensor 42 is determined to be position # 3, # 4 or “other” (step S35). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S36), and proceeds to the error processing of step S23 (see FIG. 7).

  In step S31, the PCS 1 determines that the current flowing through the U-phase load 31u has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S31). (Yes), the process proceeds to step S32.

  In step S32, the PCS 1 energizes the CT2 sensor 42, and if the power 2 consumed by the U-phase load 31u is positive (step S32 → Yes), the state of the CT2 sensor 42 is position # 2 or position # 6. (Step S33), the process proceeds to step S80 in FIG. The PCS 1 determines that the state of the CT2 sensor 42 is the position # 1 or the position # 5 if the electric power 2 consumed by the U-phase load 31u by energizing the CT2 sensor 42 is negative (step S32 → No) ( Step S34), the process proceeds to Step S100 of FIG.

FIG. 9 is a flowchart showing the V-phase load inspection (part 1).
In step S40, the PCS 1 uses the CT1 sensor 41 and the CT2 sensor 42 to measure the current when the V-phase load 31v is turned on and the current when the V-phase load 31v is turned off. Deviation between ON power and OFF power is calculated.

  When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 exceeds the threshold value, the PCS 1 determines that the current flowing through the V-phase load 31v has passed the CT1 sensor 41 (step S41 → Yes), It is determined that the state of the CT1 sensor 41 is position # 6 (step S42). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S43), and proceeds to the error processing of step S23 (see FIG. 7).

  When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 is equal to or less than the threshold value, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT1 sensor 41 (Step S41 → No). It is determined that the state of the CT1 sensor 41 is position # 2 (step S44), and the process proceeds to step S45.

  In step S45, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S45). → No), it is determined that the state of the CT2 sensor 42 is “other” (step S50). Since this is an unacceptable combination, PCS1 adds 1 to the number of repetitions (step S51), and step S23 (see FIG. 7). ) Proceed to error handling.

In step S45, the PCS 1 determines that the current flowing through the V-phase load 31v energizes the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S45). (Yes), the state of the CT2 sensor 42 is determined to be position # 3 or position # 4 (step S46), and the process proceeds to step S47.
In step S47, the PCS 1 determines that the state of the CT2 sensor 42 is the position # 4 if the power 2 consumed by the V-phase load 31v by energizing the CT2 sensor 42 is positive (step S47 → Yes) ( Step S48), the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 2.

  In step S47, the PCS 1 determines that the state of the CT1 sensor 41 is the position # 3 if the power 2 consumed by the V-phase load 31v by energizing the CT2 sensor 42 is negative (step S47 → No) ( In step S49), the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 2.

FIG. 10 is a flowchart showing the V-phase load inspection (part 2).
In step S60, the PCS 1 uses the CT1 sensor 41 and the CT2 sensor 42 to measure the ON-state current and the OFF-state current of the V-phase load 31v to obtain the ON power and OFF power of the V-phase load 31v. Deviation between ON power and OFF power is calculated.

  When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 exceeds the threshold value, the PCS 1 determines that the current flowing through the V-phase load 31v has passed the CT1 sensor 41 (step S61 → Yes), It is determined that the state of the CT1 sensor 41 is position # 5 (step S62). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S63), and proceeds to the error processing of step S23 (see FIG. 7).

  When the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 is equal to or less than the threshold value, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT1 sensor 41 (step S61 → No). It is determined that the state of the CT1 sensor 41 is position # 1 (step S64), and the process proceeds to step S65.

  In step S65, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S65). → No), it is determined that the state of the CT2 sensor 42 is “other” (step S70). Since this is an unacceptable combination, the PCS1 adds 1 to the number of repetitions (step S71), and step S23 (see FIG. 7). ) Proceed to error handling.

  In step S65, the PCS 1 determines that the current flowing through the V-phase load 31v energizes the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S65). (Yes), it is determined that the state of the CT2 sensor 42 is position # 3 or position # 4 (step S66), and the process proceeds to step S67.

In step S67, the PCS 1 determines that the state of the CT2 sensor 42 is the position # 4 if the power 2 consumed by the V-phase load 31v by energizing the CT2 sensor 42 is positive (step S67 → Yes) ( Step S68), the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 1.
In step S67, the PCS 1 determines that the state of the CT1 sensor 41 is the position # 3 if the power 2 consumed by the V-phase load 31v by energizing the CT2 sensor 42 is negative (step S67 → No) ( In step S69), the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 1.

FIG. 11 is a flowchart showing the V-phase load inspection (part 3).
In step S80, the PCS 1 measures the ON and OFF currents of the V-phase load 31v by using the CT1 sensor 41 and the CT2 sensor 42 to obtain the ON power and OFF power of the V-phase load 31v. Deviation between ON power and OFF power is calculated.

In step S81, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT1 sensor 41 when the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 is equal to or less than the threshold (step S81). → No), it is determined that the state of the CT1 sensor 41 is “other” (step S93). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S94), and proceeds to the error processing of step S23 (see FIG. 7).
In step S81, the PCS 1 determines that the current flowing through the V-phase load 31v energizes the CT1 sensor 41 when the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 exceeds the threshold (step S81). (Yes), the process proceeds to step S82.

  In step S82, the PCS 1 determines that the state of the CT2 sensor 42 is the position # 4 if the power 1 consumed by the V-phase load 31v by energizing the CT1 sensor 41 is positive (step S82 → Yes) ( The process proceeds to step S83) and step S84. If the electric power 1 consumed by the V-phase load 31v after energizing the CT1 sensor 41 is negative (step S82 → No), the PCS 1 determines that the state of the CT2 sensor 42 is position # 3 (step S88). The process proceeds to step S89.

  In step S84, the PCS 1 determines that the current flowing through the V-phase load 31v has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S84). (Yes), it is determined that the state of the CT2 sensor 42 is the position # 6 (step S85). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S86), and proceeds to the error processing of step S23 (see FIG. 7).

  In step S84, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S84). → No), it is determined that the state of the CT2 sensor 42 is the position # 2 (step S87), and the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 4.

  In step S89, the PCS 1 determines that the current flowing through the V-phase load 31v has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S89). (Yes), it is determined that the state of the CT2 sensor 42 is the position # 6 (step S90). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S91), and proceeds to the error process of step S23 (see FIG. 7).

  In step S89, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S89). → No), it is determined that the state of the CT2 sensor 42 is the position # 2 (step S92), and the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 3.

FIG. 12 is a flowchart showing the V-phase load inspection (part 4).
In step S100, the PCS 1 uses the CT1 sensor 41 and the CT2 sensor 42 to measure the current when the V-phase load 31v is turned on and the current when the V-phase load 31v is turned off. Deviation between ON power and OFF power is calculated.

In step S101, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT1 sensor 41 when the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 is equal to or less than the threshold (step S101). → No), it is determined that the state of the CT1 sensor 41 is “other” (step S113). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S114), and proceeds to the error process of step S23 (see FIG. 7).
In step S101, the PCS 1 determines that the current flowing through the V-phase load 31v energizes the CT1 sensor 41 when the absolute value of the deviation between the ON power and the OFF power of the CT1 sensor 41 exceeds the threshold (step S101). (Yes), the process proceeds to step S102.

  In step S102, the PCS 1 determines that the state of the CT2 sensor 42 is the position # 4 if the electric power 1 consumed by the V-phase load 31v by energizing the CT1 sensor 41 is positive (step S102 → Yes) ( The process proceeds to step S103) and step S104. If the electric power 1 consumed by the V-phase load 31v after energizing the CT1 sensor 41 is negative (step S102 → No), the PCS1 determines that the state of the CT2 sensor 42 is position # 3 (step S108). The process proceeds to step S109.

  In step S104, the PCS 1 determines that the current flowing through the V-phase load 31v energizes the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S104). (Yes), it is determined that the state of the CT2 sensor 42 is the position # 5 (step S105). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S106), and proceeds to the error process of step S23 (see FIG. 7).

  In step S104, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S104). → No), it is determined that the state of the CT2 sensor 42 is the position # 1 (step S107), and the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 4.

  In step S109, the PCS 1 determines that the current flowing through the V-phase load 31v has energized the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 exceeds the threshold (step S109). (Yes), it is determined that the state of the CT2 sensor 42 is the position # 5 (step S110). Since this is an unacceptable combination, the PCS 1 adds 1 to the number of repetitions (step S111), and proceeds to the error processing of step S23 (see FIG. 7).

  In step S109, the PCS 1 determines that the current flowing through the V-phase load 31v is not energizing the CT2 sensor 42 when the absolute value of the deviation between the ON power and the OFF power of the CT2 sensor 42 is equal to or less than the threshold (step S109). → No), it is determined that the state of the CT2 sensor 42 is the position # 1 (step S112), and the process ends normally. At this time, the state of the CT1 sensor 41 is determined to be position # 3.

  As described above, the cogeneration system (S) of the present embodiment is in any one of the U, N, and V phases constituting the three-phase alternating current connected to the home load (6). The first and second current sensors (41, 42) to be mounted, the U-phase load (31u) that can be energized between the U-N phases of the three-phase AC, and the V-N phase of the three-phase AC can be energized. Measurement results of the first and second current sensors (41, 42) when the V-phase load (31v) and the U-phase load (31u) are not energized, and the U-phase load (31u). From the deviation from the measurement results of the first and second current sensors (41, 42) when energized, the U-phase loads (31u) of the first and second current sensors (41, 42). ) To determine the presence / absence of energization and the energization direction, and pass it to the V-phase load (31v). The measurement results of the first and second current sensors (41, 42) when they are not made and the first and second current sensors (41, 42) when the V-phase load (31v) is energized. 42) from the deviation from the measurement result of the first and second current sensors (41, 42), the presence or absence of energization by the V-phase load (31v) and the energization direction are determined, and the first, The determination part (1) which determines the attachment line and direction of each 2nd current sensor (41, 42) is provided.

  Therefore, according to the present embodiment, the attachment positions of the CT1 sensor 41 and the CT2 sensor 42 can be easily determined. Further, when the attachment positions of the CT1 sensor 41 and the CT2 sensor 42 cannot be allowed, an error can be notified.

In the present embodiment, two 100 V loads (glow heaters) used in the fuel cell system are connected to the U-N phase and the V-N phase, which are used as the U-phase load 31u and the V-phase load 31v. Therefore, the attachment line and direction of the CT1 sensor 41 and the CT2 sensor 42 can be determined without an additional device. Further, by using the same load (glow heater), the load current becomes the same level in the U phase and the V phase, and more reliable determination is possible.
Further, by using random numbers for the load energization time and the load energization timing, synchronization with the current of the household load 6 connected to the switchboard is avoided, and the attachment lines and directions of the CT1 sensor 41 and the CT2 sensor 42 are more accurately determined. Can be determined. Therefore, the determination can be made without stopping the household load 6.

  As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to the structure described in the said embodiment, Including suitably combining thru | or selecting the structure described in embodiment, The configuration can be changed as appropriate without departing from the spirit of the invention.

For example, although the CT1 sensor 41 and the CT2 sensor 42 are galvanometers in the above embodiment, they may be current sensors, for example, Hall sensors.
In the above embodiment, the cogeneration system S generates power using a fuel cell, but other power generation modes may be used and are not limited. Further, the U-phase load 31u and the V-phase load 31v are not limited to the glow heater of the fuel cell, and may be loads that are used in any power generation mode.

S Cogeneration system 1 PCS (Power Conditioning System)
2 ECU (electronic control unit)
3 Auxiliary machine 31u U-phase load (Glow heater)
31v V-phase load (Glow heater)
41 CT1 sensor (first current sensor)
42 CT2 sensor (second current sensor)
6 Domestic load 9 System power supply 91 U-phase wiring 92 V-phase wiring 93 N-phase wiring

Claims (5)

A first current sensor and a second current sensor respectively attached to any one of U, N, and V phases constituting a three-phase alternating current connected to a home load;
A U-phase load that can be energized between the U-N phases of the three-phase alternating current;
A V-phase load that can be energized between V-N phases of the three-phase alternating current;
The measurement results of the first and second current sensors when the U-phase load is not energized and the measurement results of the first and second current sensors when the U-phase load is energized From the deviation, it is determined whether or not the first and second current sensors are energized by the U-phase load and the energization direction, and the first and second currents when the V-phase load is not energized. Energization of each of the first and second current sensors by the V-phase load is based on a deviation between the measurement result of the sensor and the measurement results of the first and second current sensors when the V-phase load is energized. A determination unit that determines the presence / absence and the energization direction of the first and second current sensors, and determines the attachment line and direction of each of the first and second current sensors;
Cogeneration system characterized by comprising. The determination unit uses random numbers for energization time and energization timing of the U-phase load and the V-phase load.
The cogeneration system according to claim 1. The determination unit notifies an error if the mounting lines and orientations of the first and second current sensors are not acceptable.
The cogeneration system according to claim 1 or 2, wherein The U-phase load and the V-phase load are glow heaters used in the cogeneration system.
The cogeneration system according to any one of claims 1 to 3, wherein A first current sensor and a second current sensor respectively attached to any one of U, N, and V phases constituting a three-phase alternating current connected to a home load;
A U-phase load that can be energized between the U-N phases of the three-phase alternating current;
A V-phase load that can be energized between V-N phases of the three-phase alternating current;
A determination unit;
A sensor check method executed by a cogeneration system equipped with
The determination unit
Measure the current with each of the first and second current sensors when the U-phase load is not energized,
Current is measured by each of the first and second current sensors when the U-phase load is energized,
Determining whether or not the first and second current sensors are energized by the U-phase load and the energization direction;
The current is measured by each of the first and second current sensors when the V-phase load is not energized,
Current is measured by each of the first and second current sensors when the V-phase load is energized,
Determining the presence and direction of energization by the V-phase load of each of the first and second current sensors, and determining the attachment line and direction of each of the first and second current sensors;
A sensor check method for a cogeneration system.

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