JP5973495B2 - Power measuring apparatus and power measuring method - Google Patents

Description

  The present invention relates to a technique for measuring power in a connection path for supplying power from a power generator to a load.

  FIG. 7 schematically shows a configuration example of the power generation system (see, for example, Patent Document 1). The power generation system 100 includes a power generation device 101 and a power measurement device 102. The power generation device 101 is, for example, a fuel cell (a device that generates power by converting chemical energy into electrical energy) and has a configuration for generating power. This power generator 101 is a single-phase three-wire system and is electrically connected to a commercial power source 103 via a load 105. In other words, the power generation apparatus 101 is electrically connected to the commercial power supply 103 by three conductors of two voltage lines 106 and 107 and a neutral line (a line grounded to the ground) 108.

  The power measuring device 102 includes current sensors 111 and 112, a voltage sensor 113, a heater 114, and a control device 115. The current sensor 111 is interposed in the voltage line 106 at a portion closer to the commercial power supply 103 than the load 105, and has a configuration for detecting a current value of a current flowing through the interposed portion in the voltage line 106. The current sensor 112 is interposed in the voltage line 107 at a portion closer to the commercial power supply 103 than the load 105, and has a configuration for detecting a current value of a current flowing through the interposed portion in the voltage line 107. The voltage sensor 113 is connected to the voltage lines 106 and 107 and the neutral line 108 closer to the commercial power supply 103 than the load 105. The voltage sensor 113 has a configuration for detecting a potential difference (voltage value) between the voltage line 106 and the neutral line 108 and a potential difference (voltage value) between the voltage line 107 and the neutral line 108. Yes.

  The control device 115 includes, for example, a CPU (Central Processing Unit) (not shown), and has a function of controlling the overall operation of the power measurement device 102 by the CPU. For example, the control device 115 has a function of calculating a purchased power value and a sold power value using current values and voltage values detected by the current sensors 111 and 112 and the voltage sensor 113. The purchased power value is a value of power supplied from the commercial power supply 103 to the load 105. The sold power value is a value of power flowing from the power generation apparatus 101 to the commercial power supply 103 side.

  Here, it is assumed that the attachment (connection) state of the current sensors 111 and 112 and the voltage sensor 113 is determined as follows. That is, when power is supplied from the commercial power supply 103 toward the load 105, the sign of the power value obtained by multiplying each current value by the current sensors 111 and 112 by the voltage value by the voltage sensor 113 becomes positive. Thus, the sensors 111, 112, and 113 are attached. In other words, when power flows from the power generation apparatus 101 toward the commercial power supply 103, the sign of the power value obtained by multiplying each current value by the current sensors 111 and 112 by the voltage value by the voltage sensor 113 is negative. The sensors 111, 112, and 113 are attached so that

  In such a case, when the sign of the calculated power value is positive, the control device 115 is in a state in which power is being supplied from the commercial power supply 103 toward the load 105. Is calculated as the amount of electric power purchased. In addition, when the sign of the calculated power value is negative, the control device 115 is in a state in which power is flowing from the power generation device 101 toward the commercial power supply 103. Calculate as

  By the way, the current sensors 111 and 112 and the voltage sensor 113 may be attached in an incorrect state. Due to the sensor attachment error, the sign of the power value calculated by the control device 115 may be inappropriate. That is, when power is flowing from the power generation apparatus 101 toward the commercial power supply 103, there is a sign error situation where the sign of the power value calculated by the control apparatus 115 becomes negative but becomes positive. Occur. In other words, due to a sensor attachment error, there arises a problem that the control device 115 calculates the purchased power value and the sold power value in reverse.

  In order to prevent such a problem from occurring, the power measuring apparatus 102 has the following functions. That is, in a state in which the power generation apparatus 101 is not generating power, the control apparatus 115 drives the heater 114, and the power value based on the current value by the current sensors 111 and 112 and the voltage value by the voltage sensor 113 while the heater 114 is being driven. Is calculated. When the calculated power value is equal to or less than the threshold value, the control device 115 determines that the current sensors 111 and 112 are attached in an incorrect state, and reverses the sign of the power value calculated thereafter. The code is changed (corrected). With such a function, the control device 115 tries to prevent an erroneous measurement problem caused by an attachment error of the current sensors 111 and 112.

JP 2009-118673 A

  By the way, the power measuring device 102 (control device 115) calculates (measures) the power value every moment, and stores the calculated power value in a storage unit (not shown). It is assumed that the power measurement device 102 detects an attachment error of the current sensors 111 and 112 in such a state that the power value is stored in the storage unit every moment. In this case, as described above, the power measuring apparatus 102 corrects the sign of the power value calculated after detecting the attachment error to the opposite sign, and stores the corrected power value in the storage unit. . Thereby, the power measurement apparatus 102 can avoid the problem that an incorrect power value is continuously stored in the storage unit.

  However, the power value of the code error stored in the storage unit until the power measuring device 102 detects the mounting error of the current sensors 111 and 112 remains unchanged. For this reason, for example, when calculating each total value of the purchased power value and the sold power value in the set period, if a plurality of power values used for the calculation include a power value of a code error The power measuring device 102 cannot calculate the total sum of the purchased power value and the sold power value.

  The present invention has been devised to solve the above problems. That is, the main object of the present invention is to avoid the problem of erroneous measurement of the power value caused by the sensor mounting error, and also to correct the power value of the past code error, thereby improving the reliability of the power measurement. It is to provide a technology that can be enhanced.

In order to achieve the above object, the power measuring apparatus of the present invention is provided with:
The current value output by the main-side current sensor that detects the current value of the current flowing through the path portion on the main power generator side of the load in the connection path that electrically connects the main power generator and the sub power generator via the load And a supply power calculation unit that calculates a power value of power supplied from the main power generator to the load as a supply power value based on a voltage value output by a voltage sensor that detects a voltage value of the connection path. ,
Based on the current value output by the sub-side current sensor that detects the current value of the current flowing in the path portion on the sub power generator side of the load in the connection path, and the voltage value output by the voltage sensor, A generated power calculation unit that calculates a power value of power output from the sub power generator as a generated power value;
The supply power value calculated by the supply power calculation unit and the generated power value calculated by the generated power calculation unit are respectively calculated based on the time when the voltage value and the current value used for calculation are detected. A writing unit that writes to an internal or external storage unit in a manner associated with the time information to be represented;
When it is detected that the sign of the power supply value calculated by the power supply calculation unit is not appropriate using the power supply value and the generated power value, the sign of the power supply value is reversed. A code control unit for controlling the supply power calculation unit to be a code;
When it is detected that the sign of the supplied power value is not appropriate, it is detected that the sign is not appropriate from the measurement start time based on the measurement start time information acquired when the power measurement is started. And a correction unit that changes the sign of the supplied power value written in the storage unit to a reverse sign.

Moreover, the power measurement method of the present invention includes:
The current value output by the main-side current sensor that detects the current value of the current flowing through the path portion on the main power generator side of the load in the connection path that electrically connects the main power generator and the sub power generator via the load And based on the voltage value output from the voltage sensor that detects the voltage value of the connection path, the power value of the power supplied from the main power generation device to the load is calculated as the supply power value,
Based on the current value output by the sub-side current sensor that detects the current value of the current flowing in the path portion on the sub power generator side of the load in the connection path, and the voltage value output by the voltage sensor, Calculate the power value of the power output from the sub power generator as the generated power value,
The calculated supply power value and the generated power value are stored in an internal or external storage unit in a manner associated with time information indicating the time when the voltage value and the current value used for calculation are detected, respectively. writing,
When the supply power value and the generated power value are used to detect that the sign of the supply power value is not appropriate, control is performed so that the calculated sign of the supply power value is reversed. And
When it is detected that the sign of the supplied power value is not appropriate, it is detected that the sign is not appropriate from the measurement start time based on the measurement start time information acquired when the power measurement is started. The sign of the supplied power value written in the storage unit during the period until the time is changed to the opposite sign.

  According to the present invention, it is possible to avoid the problem of erroneous measurement of the power value due to a sensor mounting error, and to correct the power value of the past code error, thereby improving the reliability of the power measurement.

It is a block diagram which simplifies and represents the structure of the power measuring device of 1st Embodiment which concerns on this invention. It is a block diagram which simplifies and represents the structure of the electric power measurement apparatus of 2nd Embodiment which concerns on this invention. It is a figure which represents typically the electric current which flows into the connection path | route in 2nd Embodiment. It is a block diagram which simplifies and represents the structure of the code | symbol control part in 2nd Embodiment. It is a flowchart showing the operation example of the control apparatus which comprises the electric power measurement apparatus of 2nd Embodiment. It is a time chart explaining operation | movement of the electric power measurement apparatus of 2nd Embodiment. It is a block diagram showing the example of 1 structure of an electric power system.

  Embodiments according to the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a simplified configuration of the power measuring apparatus according to the first embodiment of the present invention. In the case where the sub power generation device 11 is electrically connected to the main power generation device 10 via the load 12, the power measuring device 1 includes the power value of power supplied from the main power generation device 10 to the load 12, and the sub power generation device 10. This is a device that can measure the power value of the power generated by the power generation device 11. The power measuring apparatus 1 uses detection values output from the main-side current sensor 13, the sub-side current sensor 14, and the voltage sensor 15, respectively. The main-side current sensor 13 is provided in a path portion closer to the main power generation device 10 than the load 12 in the connection path 16 that electrically connects the main power generation device 10 and the sub power generation device 11, and a current flowing through the path portion. A configuration for detecting the current value is provided. The sub-side current sensor 14 is provided in a path portion closer to the sub power generation device 11 than the load 12 in the connection path 16 and has a configuration for detecting a current value of a current flowing through the path portion. The voltage sensor 15 is connected to the connection path 16, and here has a configuration for detecting a potential difference (voltage) between the ground that is the reference potential and the connection path 16.

  The power measuring apparatus 1 according to the first embodiment includes a supply power calculation unit 3, a generated power calculation unit 4, a code control unit 5, a writing unit 6, a correction unit 7, and a storage unit 8. . The power measuring device 1 may use an external storage unit 8 instead of the built-in storage unit 8.

  Based on the current value output from the main-side current sensor 13 and the voltage value output from the voltage sensor 15, the supplied power calculation unit 3 is a power value of power supplied from the main power generation device 10 to the load 12 (hereinafter, (Also referred to as supply power value).

  Based on the current value output from the sub-side current sensor 14 and the voltage value output from the voltage sensor 15, the generated power calculation unit 3 generates a power value of power generated by the sub power generation device 11 (hereinafter also referred to as a generated power value). It has a function to calculate

  The writing unit 6 represents the time when the voltage value and the current value used for the calculation are calculated based on the supply power value calculated by the supply power calculation unit 3 and the generated power value calculated by the generated power calculation unit 4, respectively. A function of writing to the storage unit 8 is provided in a manner associated with the time information. Note that the time information may be time information, not limited to time information, and may be, for example, information on elapsed time from the start of measurement.

  The code control unit 5 uses the supply power value calculated by the supply power calculation unit 3 and the generated power value calculated by the generated power calculation unit 4 to supply power value calculated by the supply power calculation unit 3 Has a function of detecting that the sign of is not appropriate. In addition, when the sign control unit 5 detects that the sign of the supply power value by the supply power calculation unit 3 is not appropriate, the sign control unit 5 outputs the sign of the supply power value output from the supply power calculation unit 3 to the opposite sign. A function for controlling the supplied power calculation unit 3 is provided.

  The correction unit 7 has a function of operating as follows when it is detected that the sign of the supply power value by the supply power calculation unit 3 is not appropriate. That is, the correction unit 7 stores the storage unit in a period from the measurement start time based on the measurement start time information acquired when the power measurement is started until the sign of the supplied power value is detected to be inappropriate. The sign of the supplied power value written in 8 is changed (corrected) to the opposite sign.

  In the power measuring apparatus 1 of the first embodiment, when it is detected that the sign of the supply power value by the supply power calculation unit 3 is not appropriate, the supply output from the supply power calculation unit 3 after detection is detected. It has a control function to change the sign of the power value to the opposite sign. For this reason, the power measuring apparatus 1 can output a supplied power value with a correct sign, even if the main-side current sensor 13 and the voltage sensor 15 are not attached as set. In addition, the power measuring apparatus 1 changes (corrects) the sign of the power error value of the sign error written in the storage unit 8 before it is detected that the calculated power supply value is not appropriate. It has a function to do. Thereby, the power measuring device 1 can improve the accuracy of the calculation result (for example, the total value of the supplied power values in the set period) using the past data written in the storage unit 8. Thereby, the power measuring apparatus 1 can improve the reliability with respect to the power measurement.

(Second Embodiment)
The second embodiment according to the present invention will be described below.

  FIG. 2 is a block diagram showing a simplified configuration of the power measuring apparatus according to the second embodiment of the present invention. The power measurement device 20 of the second embodiment has the following power value when the power generation device 22 that is a sub power generation device is electrically connected to the commercial power source 24 that is the main power generation device via a load 23. It is a device that can measure. That is, the power value measured by the power measuring device 20 includes the value of power supplied from the commercial power supply 24 to the load 23 (hereinafter also referred to as supply power value) and the value of power generated by the sub power generator 22 ( Hereinafter, it is also referred to as a generated power value).

  In the second embodiment, the power generation device 22 is, for example, a solar power generation device. In the second embodiment, AC power is output. The power generator 22 is electrically connected to a commercial power source 24 with a single-phase three-wire system. That is, the power generation device 22 is electrically connected to the commercial power supply 24 through a connection path 25 formed by the first voltage line 26, the second voltage line 27, and the neutral line 28 connected to the ground. Yes. The commercial power source 24 is a main power source that supplies AC power to the load 23. The load 23 is connected to two conductors selected from the voltage lines 26 and 27 and the neutral line 28 based on the rated voltage determined by the specifications. The load 23 receives power from the commercial power supply 24 and the power generator 22. Is supplied. Here, when the amount of power generated by the power generation device 22 is larger than the amount of power consumed by the load 23, a state called reverse power flow in which current (electric power) flows from the power generation device 22 to the commercial power supply 24 is brought about. . Note that the load 23 is not limited to one and may be a plurality.

  The power measuring device 20 of the second embodiment includes a first main-side current sensor 30, a second main-side current sensor 31, a power-generation-side current sensor 32 that is a sub-side current sensor, a first voltage sensor 34, A second voltage sensor 35. Further, the power measurement device 20 includes a supply power calculation unit 37, a generated power calculation unit 38, a code control unit 39, a control device 40, a storage unit 41, a display unit 42, and a reset operation that is an information input unit. Part 43. Note that the power measurement device 20 may use an external storage unit as the storage unit 41 instead of the built-in storage unit 41.

  The first main-side current sensor 30 (hereinafter also referred to as current sensor 30 for short) is interposed in the voltage line 26 at a portion closer to the commercial power supply 24 than the load 23, and the current value of the current flowing through the interposed portion. Is output.

  The second main-side current sensor 31 (hereinafter also referred to as current sensor 31 for short) is interposed in the voltage line 27 at a portion closer to the commercial power supply 24 than the load 23, and the current value of the current flowing through the interposed portion. Is output.

  The power generation side current sensor 32 (hereinafter also referred to as the current sensor 32 for short) is interposed in the voltage line 26 at a portion closer to the power generation device 22 than the load 23, and outputs a current value of a current flowing through the interposed portion. It has a configuration to do.

  The first voltage sensor 34 (hereinafter also referred to as voltage sensor 34 for short) is connected to the voltage line 26 and the neutral line 28 and has a configuration for detecting a potential difference (voltage) of the voltage line 26 with respect to the neutral line 28. Yes. The second voltage sensor 35 (hereinafter also referred to as voltage sensor 35 for short) is connected to the voltage line 27 and the neutral line 28 and has a configuration for detecting a potential difference (voltage) of the voltage line 27 with respect to the neutral line 28. Yes.

  In the second embodiment, when the current sensor 30 and the voltage sensor 34 are attached to the connection path 25 as set, a power value (first value) obtained by multiplying the current value by the current sensor 30 and the voltage value by the voltage sensor 34. The sign of (1 supply power value) is as follows. That is, when power is supplied from the commercial power supply 24 to the load 23, the sign of the first supply power value is positive. In addition, when power is flowing from the power generation device 22 toward the commercial power supply 24, the sign of the first supply power value is negative. Furthermore, in a state where the current sensor 31 and the voltage sensor 35 are attached to the connection path 25 as set, a power value (second supply power value) obtained by multiplying the current value by the current sensor 31 and the voltage value by the voltage sensor 35. The sign of is as follows. That is, when power is supplied from the commercial power supply 24 to the load 23, the sign of the second supply power value is positive. In addition, when power is flowing from the power generation device 22 toward the commercial power supply 24, the sign of the second supply power value is negative.

  The supply power calculation unit 37 includes a first supply power calculator 44 and a second supply power calculator 45. The first supply power calculator 44 multiplies the current value by the current sensor 30 by the voltage value by the voltage sensor 34, thereby energizing the portion of the voltage line 26 that is closer to the commercial power supply 24 than the load 23. The power value is calculated as a first supply power value. In the second embodiment, since the power flowing through the voltage line 26 is alternating current, the first supply power calculator 44 supplies the average power value for a predetermined period of the alternating current for the first time for each period. The power value is calculated every moment. To give a specific example, when the frequency of the alternating current flowing through the voltage line 26 is 50 hertz, when set to output an average power value for one cycle of the alternating current, the first supply power calculator 44 is: An average power value for 20 milliseconds is calculated as a supplied power value about every 20 milliseconds.

  In the second embodiment, the first supply power calculator 44 may receive a sign inversion signal representing a command to change the sign of the calculated value to the opposite sign from the sign control unit 39. In this case, Outputs a value obtained by changing the sign of the calculated value to the opposite sign as the first supply power value.

  The second supply power calculator 45 multiplies the current value by the current sensor 31 by the voltage value by the voltage sensor 35, thereby energizing the portion of the voltage line 27 closer to the commercial power supply 24 than the load 23. The power value is calculated as the second supply power value. Similarly to the first supply power calculator 44, the second supply power calculator 45 calculates an average power value for a predetermined period of AC as a second supply power value for each period. Further, when the sign supply signal is received from the sign control unit 39, the second supply power calculator 45 outputs a value obtained by changing the sign of the calculated value to the opposite sign as the second supply power value.

  The generated power calculation unit 38 includes a first generated power calculator 46 and a second generated power calculator 47. The first generated power calculator 46 multiplies the current value by the current sensor 32 and the voltage value by the voltage sensor 34, thereby energizing the portion of the voltage line 26 that is closer to the power generator 22 than the load 23. The power value is calculated as the first generated power value. The second generated power calculator 47 multiplies the current value by the current sensor 32 and the voltage value by the voltage sensor 35, thereby energizing the portion of the voltage line 27 closer to the power generator 22 than the load 23. Is provided as a second generated power value. Similarly to the first supply power calculator 44, the first generated power calculator 46 and the second generated power calculator 47 also use the average power value for a predetermined period of AC as the generated power value for each period. calculate. In the second embodiment, the first generated power calculator 46 and the second generated power calculator 47 are configured such that the calculated first generated power value or the sign of the second generated power value is always positive. Has been.

  The reset operation unit 43 includes, for example, a manual switch (not shown) that is pressed by an operator or the like, and a signal generation unit (not shown) that generates a reset signal when the manual switch is pressed. In the second embodiment, for example, the timing for depressing the manual switch of the reset operation unit 43 is predetermined. The pressing timing is when the power measuring device 20 is installed, when the current sensors 30 and 31 and the voltage sensors 34 and 35 are reattached, and when the current sensors 30 and 31 and the voltage sensors 34 and 35 are replaced. It is.

  The sign control unit 39 uses the calculated values calculated by the supply power calculation unit 37 and the generated power calculation unit 38, respectively, to output the first supply power value and the second supply power value output from the supply power calculation unit 37, respectively. It has a function that can detect that the sign of is not appropriate.

Here, it is possible to detect that the sign of each of the first supply power value and the second supply power value is not appropriate by using the calculated values calculated by the supply power calculation unit 37 and the generated power calculation unit 38, respectively. Will be described with reference to FIG. FIG. 3 is a model diagram schematically showing the current supply state in the connection path 25. In this description, the current value of the current supplied from the commercial power supply 24 to the load 23a is assumed to be Iza. Let Izb be the current value of the current flowing from the commercial power supply 24 to the load 23b. Let Izc be the current value of the current flowing from the commercial power supply 24 to the load 23c. In the portion of the voltage line 26 closer to the commercial power supply 24 than the load 23, the current value of the current flowing from the commercial power supply 24 to the loads 23a and 23c is Iz1 (Iz1 = Iza + Izc). In the portion of the voltage line 27 closer to the commercial power supply 24 than the load 23, the current value of the current flowing from the commercial power supply 24 side to the loads 23b and 23c is Iz2 (Iz2 = Izb + Izc). Furthermore, the current value of the current that flows through the connection path 25 when the power generation device 22 generates power is defined as Ipv. The current value detected by the current sensor 30 is I ₃₀ . The current value detected by the current sensor 31 is I ₃₁ . The voltage value detected by the voltage sensor 34 and V _34. The voltage value detected by the voltage sensor 35 and V _35.

  First, the first supply power value Wz1 will be described.

The first supply power value Wz1 is a value obtained by multiplying the current value I ₃₀ detected by the current sensor ₃₀ and the voltage value V ₃₄ detected by the voltage sensor 34. Further, the current I ₃₀ detected by the current sensor 30 can be expressed by Expression (1). Thus, the first supply power value is expressed as shown in Equation (2).

I ₃₀ = Iz1-Ipv (1)
_{Wz1 = I 30 × V 34 =} (Iz1-Ipv) × V 34 ····· (2)

  A reverse power flow (that is, a phenomenon in which the power generated by the power generation device 22 flows to the commercial power supply 24 side) occurs when the amount of power generated by the power generation device 22 is greater than the amount of power consumed by the load 23 (23a, 23b, 23c). This is a phenomenon in which surplus power flows to the commercial power supply 24 side. In the state where the reverse power flow is generated, the current value Ipv of the current generated by the power generator 22 is larger than the current value Iz1 of the current flowing from the commercial power supply 24 side to the load 23 side (Iz1 <Ipv). From this, in the state where the reverse power flow is generated, the first supply power value Wz1 represented by the equation (2) is negative. Further, since the first supply power value Wz1 represented by the expression (2) can be expressed as the expression (3), the expression (4) is established in the state where the reverse power flow is generated.

Wz1 = (Iz1-Ipv) × V 34 = Iz1 × V 34 -Ipv × V 34 ····· (3)
_{Iz1 × V 34 -Ipv × V 34} <0 ····· (4)

Further, in the state where the reverse power flow is generated, surplus power that has not been consumed by the load 23 out of the power generated by the power generation device 22 flows to the commercial power supply 24 side, so the absolute value of the first supply power value Wz1 is It does not exceed the absolute value of the first generator power value _{Wp1 (Wp1 = Ipv × V 34} ). Thereby, when the sign of the first supply power value Wz1 is negative, the equation (5) is established. Expression (6) is an expression obtained by rewriting Expression (5) using Expression (3) or the like.

| Wz1 | <| Wp1 | ... (5)
| Iz1 × V ₃₄ −Ipv × V ₃₄ | <| Ipv × V ₃₄ | (6)

  However, due to the fact that the current sensor 30 and the voltage sensor 34 are in an erroneous mounting state, there are cases where the expression (5) does not hold even if the sign of the first supply power value Wz1 is negative. That is, when no reverse power flow has occurred, the absolute value of the first supply power value Wz1 is not restricted by the amount of power generated by the power generation device 22, so the absolute value of the first supply power value Wz1 is In some cases, the absolute value of the first generated power value Wp1 may be larger. In this case, the first sign of the first generated power value Wp1 is negative when the reverse flow does not occur due to an attachment error of the current sensor 30 or the voltage sensor 34. Even if the sign of the supplied power value Wz1 is negative, the expressions (5) and (6) do not hold.

  For this reason, when the first supply power value Wz1 is negative and Equation (7) holds, it can be determined that the sign of the first supply power value Wz1 is not appropriate.

| Iz1 × V ₃₄ −Ipv × V ₃₄ | >> | Ipv × V ₃₄ | (7)
Since it can be expressed as Iz1 = I ₃₀ + Ipv based on the formula (1), the formula (7) can be rewritten as the formula (8) by using this.

| (I ₃₀ + Ipv) × V ₃₄ −Ipv × V ₃₄ | >> | Ipv × V ₃₄ | (8)
That is, | I ₃₀ × V ₃₄ |> | Ipv × V ₃₄ |, and when rewritten, | Wz1 |> | Wp1 |. That is, when the first supply power value Wz1 is negative and the absolute value of the first supply power value Wz1 is larger than the absolute value of the first generated power value Wp1, the positive / negative of the first supply power value Wz1. It can be determined that the code is not appropriate.

  For the same reason regarding the second supply power value Wz2, the second supply power value Wz2 is negative and the absolute value of the second supply power value Wz2 is larger than the absolute value of the second generation power value Wp2. It can be determined that the sign of the second supply power value Wz2 is not appropriate.

  The sign control unit 39 includes a circuit that detects that the sign of the first supply power value Wz1 and the second supply power value Wz2 is not appropriate by comparing the supply power value and the generated power value as described above. Yes. In the second embodiment, the code control unit 39 includes a first code control circuit 50 and a second code control circuit 51. The first code control circuit 50 and the second code control circuit 51 have the same circuit configuration. FIG. 4 is a block diagram showing a simplified circuit configuration example of the first code control circuit 50 (second code control circuit 51). The circuit 50 (51) shown in FIG. 4 includes a flip-flop circuit 53 and a comparator 54.

  The comparator 54 compares the supplied power value Wz1 (Wz2) calculated by the supplied power calculator 44 (45) with the generated power value Wp1 (Wp2) calculated by the generated power calculator 46 (47), A circuit configuration for outputting an excess signal is provided in the following cases. When the comparator 54 outputs an excess signal, the supplied power value Wz1 (Wz2) is negative, and the absolute value of the supplied power value Wz1 (Wz2) is greater than the absolute value of the generated power value Wp1 (Wp2). This is also the case.

  The flip-flop circuit 53 includes a set unit S and a reset unit R that are signal input units, and an output unit Q. In the example of FIG. 4, the set unit S is electrically connected to the output unit of the comparator 54. The reset unit R is connected to the reset operation unit 43. The flip-flop circuit 53 continuously outputs a sign inversion signal from the output unit Q after the excess signal is input from the comparator 54 to the set unit S. When the reset signal is applied to the reset unit R, the sign inversion is performed. A circuit configuration for stopping signal output is provided. The sign inversion signal output from the flip-flop circuit 53 is applied to the first supply power calculator 44, the second supply power calculator 45, and the control device 40. As described above, the first power supply calculator 44 and the second power supply calculator 45 supply a value obtained by changing the sign of the calculated power value to the opposite sign when the sign inversion signal is applied. Output as a value.

  The control device 40 includes, for example, a CPU (Central Processing Unit), and controls the overall operation of the power measurement device 20 by executing a computer program (program) read from the storage unit 41, for example, by the CPU. It has. In the second embodiment, the control device 40 includes a correction unit 56 and a writing unit 57 as functional units.

  The writing unit 57 represents the time when the power values output from the first supply power calculator 44, the second supply power calculator 45, the first generated power calculator 46, and the second generated power calculator 47 are calculated. A function of writing in the storage unit 41 is provided in a manner associated with the time information. The time information associated with the power value may be time information by a clock mechanism built in the control device 40, or may be other information representing time other than the time information.

  In addition, when the reset operation unit 43 is operated and the reset signal is output from the reset input unit 43, the writing unit 57 uses the information indicating the time when the reset signal is output as the measurement start time information. A function of storing in the storage unit 41 is provided.

  When the correction unit 56 detects that the sign inversion signal is output from the first code control circuit 50 of the code control unit 39, the correction unit 56 sets the first supply power value Wz1 written in the storage unit 41 as follows. It has a function to correct. In other words, the correction unit 56 calculates the sign of the first supply power value Wz1 calculated and written in the storage unit 41 during the period from the measurement start time stored in the storage unit 41 until the sign inversion signal is output. A function of changing to the opposite sign and updating the first supply power value Wz1 is provided. Similarly, when the correction unit 56 detects that the sign inversion signal is output from the second code control circuit 51 of the code control unit 39, the correction unit 56 outputs the second supply power value Wz2 written in the storage unit 41. Has the function to correct as follows. That is, the correction unit 56 calculates the sign of the second supply power value Wz2 calculated and written in the storage unit 41 during the period from the measurement start time stored in the storage unit 41 until the sign inversion signal is output. It has a function of changing to the opposite sign and updating the second supply power value Wz2.

  The control device 40 further includes a purchased power calculation unit (not shown). The power purchase power calculation unit calculates the total value (power purchase power value) of the power values (supply power values Wz1, Wz2) supplied and consumed from the commercial power supply 24 to the load 23 during a set period (for example, for one month). The function to calculate is provided. The display unit 42 is, for example, a liquid crystal screen, and has a function of displaying the calculated purchased power value and the like. The display content of the display unit 42 is controlled by the control device 40.

  Hereinafter, an operation example of the control device 40 will be described with reference to FIGS. 5 and 6. FIG. 5 is a flowchart illustrating an example of an operation in which the control device 40 corrects the sign of the supplied power values Wz1 and Wz2 stored in the storage unit 41. FIG. 6 is a time chart for explaining the operation of the power measuring apparatus 20. In FIG. 6, the first supply power value Wz1 and the first generated power value Wp1 written in the storage unit 41 are represented by bar graphs.

  For example, it is assumed that the operator operates the reset operation unit 43 by exchanging the current sensors 30 and 31. As a result, a reset signal is output from the reset operation unit 43 (see time T1 in FIG. 6). When the flip-flop circuit 53 of the sign control unit 39 receives the reset signal, for example, when the sign inversion signal is output from the output unit Q, the output of the sign inversion signal is stopped (time T1 in FIG. 6). (See T2).

  On the other hand, when receiving the reset signal (step S101), the control device 40 takes in information on the measurement start time (eg, time T2) from a built-in clock mechanism or the like, and writes the measurement start time in the storage unit 41 (step S102). ).

  After that, when the control device 40 receives the first supply power value Wz1, the second supply power value Wz2, the first generated power value Wp1, and the second generated power value Wp2 (step S103), these power values are respectively used as time information. The data is written in the storage unit 41 in the associated manner (step S104). And the control apparatus 40 judges whether the output of the sign inversion signal was started (step S105). That is, when the supply power calculation unit 37 and the generated power calculation unit 38 calculate the power values Wz1, Wz2, Wp1, and Wp2, the sign control unit 39 performs the sign inversion signal as described above based on the calculated power values. It is determined whether or not to start the output. If the output of the sign inversion signal has not been started by the determination of the code control unit 39, the control device 40 repeats the operations after step S103 after the determination operation of step S104. That is, the control device 40 writes the power value calculated every moment in the storage unit 41.

  Thereafter, for example, when the sign of the first supply power value Wz1 is negative, the absolute value of the first supply power value Wz1 becomes larger than the absolute value of the first generated power value Wp1 (FIG. 6). At time T6), an excess signal is output from the comparator 54 of the sign control unit 39. Thereby, the output of the sign inversion signal is started from the flip-flop circuit 53 of the sign control unit 39 (time T7 in FIG. 6).

  When detecting that the output of the sign inversion signal has been started (step S105 in FIG. 5), the correction unit 56 of the control device 40 reads information on the measurement start time (T2) from the storage unit 41. Then, the correction unit 56 changes the sign of the first supply power value Wz1 written in the storage unit 41 from the measurement start time T2 until the sign inversion signal is output (from time T2 to time T6) to the opposite sign. Change, that is, correct past data (step S106). When the output of the sign inversion signal is started, the sign of the calculated value output from the first supply power calculator 44 of the supply power calculation unit 37 is output in a state where the sign is changed to the opposite sign. Therefore, the data correction of the storage unit 41 does not have to be performed.

  In the above example, the correction unit 56 corrects the first supply power value Wz1 written in the storage unit 41. Similarly, the correction unit 56 changes the second supply power value Wz2 in the storage unit 41. In some cases.

  Since the power measurement device 20 of the second embodiment has the above-described configuration, it can improve the reliability of power measurement as in the first embodiment.

(Other embodiments)
In addition, this invention is not limited to 1st and 2nd embodiment, Various embodiment can be taken. For example, in addition to the configuration of the second embodiment, when the correction unit 56 corrects past data, the control device 40 may have a function of notifying the display unit 42 that the data correction has been performed. .

  Further, in the second embodiment, the supply power calculation unit 37 and the generated power calculation unit 38 are configured using a calculator that is separate from the control device 40. On the other hand, the control device 40 may function as the supply power calculation unit 37 and the generated power calculation unit 38. In this case, the power measuring device 20 has power values Wz1, Wz2, Wp1 based on the current values output from the current sensors 30, 31, 32 and the voltage values output from the voltage sensors 34, 35. , Wp2 is provided. Then, the control device 40 executes the computer program to calculate the power values Wz1, Wz2, Wp1, and Wp2. In this case, since the calculator can be omitted, the power measuring device 20 can be downsized.

  Furthermore, in the second embodiment, the sign control unit 39 is configured by hardware such as a comparator 53 and a flip-flop circuit 54. On the other hand, the control device 40 may be configured to function also as the code control unit 39. In this case, the power measuring device 20 calculates the supplied power when it is determined that the sign of the supplied power value needs to be changed to the opposite sign based on the comparison result between the supplied power value and the generated power value. A computer program for controlling the unit 37 is given. The control device 40 also functions as the code control unit 39 by executing the computer program. In this case, since the comparator and the flip-flop circuit can be omitted, the power measuring device 20 can be downsized.

  Furthermore, in the second embodiment, a reset operation unit 43 is provided as an information input unit to which information about the measurement start time is added. Instead of this, for example, the power measuring device 20 may include a connection unit as an information input unit connected to a personal computer (personal computer). In this case, the measurement start time information may be supplied from the personal computer to the control device 40 by the operator, and the writing unit 57 may write the measurement start time information into the storage unit 41.

  Furthermore, in 2nd Embodiment, the power generator 22 which is a sub power generator is connected to the commercial power source 24 as a main power generator. Instead of this, for example, the power generation device 22 may be configured to be connected to another power generation device (main power generation device) other than the commercial power source 24.

DESCRIPTION OF SYMBOLS 1,20 Electric power measurement apparatus 3,37 Supply electric power calculation part 4,38 Generated electric power calculation part 5,39 Code | symbol control part 10 Main power generation apparatus 11 Sub power generation apparatus 13 Main side current sensor 14 Sub side current sensor 15, 34, 35 Voltage Sensor 30, 31, 32 Current sensor 43 Reset operation part

Claims (8)

The current value output by the main-side current sensor that detects the current value of the current flowing through the path portion on the main power generator side of the load in the connection path that electrically connects the main power generator and the sub power generator via the load And a supply power calculation unit that calculates a power value of power supplied from the main power generator to the load as a supply power value based on a voltage value output by a voltage sensor that detects a voltage value of the connection path. ,
Based on the current value output by the sub-side current sensor that detects the current value of the current flowing in the path portion on the sub power generator side of the load in the connection path, and the voltage value output by the voltage sensor, A generated power calculation unit that calculates a power value of power output from the sub power generator as a generated power value;
The supply power value calculated by the supply power calculation unit and the generated power value calculated by the generated power calculation unit are respectively calculated based on the time when the voltage value and the current value used for calculation are detected. A writing unit that writes to an internal or external storage unit in a manner associated with the time information to be represented;
When it is detected that the sign of the power supply value calculated by the power supply calculation unit is not appropriate using the power supply value and the generated power value, the sign of the power supply value is reversed. A code control unit for controlling the supply power calculation unit to be a code;
When it is detected that the sign of the supplied power value is not appropriate, it is detected that the sign is not appropriate from the measurement start time based on the measurement start time information acquired when the power measurement is started. And a correction unit that changes the sign of the supplied power value written in the storage unit to a reverse sign during the period until the first time.   The power measurement device according to claim 1, further comprising an information input unit to which information on the measurement start time is added.   The sign control unit, when the sign of the supplied power value is negative and the absolute value of the supplied power value is larger than the absolute value of the generated power value, the sign of the supplied power value is The power measuring device according to claim 1 or 2, wherein the power measuring device is detected as inappropriate. The main power generator and the sub power generator are connected by a single-phase three-wire system that uses three wires of a first voltage line, a second voltage line, and a grounded neutral wire,
As the main-side current sensor, a first main-side current sensor that detects a current of the first voltage line and a second main-side current sensor that detects a current of the second voltage line are provided,
As the voltage sensor, a first voltage sensor that detects a voltage between the neutral line and the first voltage line, and a second voltage that detects a voltage between the neutral line and the second voltage line. A sensor,
The supply power calculation unit calculates a first supply power value based on a current value obtained by the first main-side current sensor and a voltage value obtained by the first voltage sensor, and a current value obtained by the second main-side current sensor. And a second supply power value based on the voltage value by the second voltage sensor,
The generated power calculation unit calculates a first generated power value based on a current value obtained by the sub-side current sensor and a voltage value obtained by the first voltage sensor, and a current value obtained by the sub-side current sensor, Based on the voltage value by the voltage sensor, the second generated power value is calculated,
When the sign control unit detects that the sign of the first supply power value is not appropriate using the first supply power value and the first generated power value, the sign control unit determines the first supply power value. The supply power calculation unit is controlled so that the positive / negative sign is reversed, and the positive / negative sign of the second supply power value is not appropriate using the second supply power value and the second generated power value. The second power supply value is controlled so that the sign of the second power supply value is reversed,
When it is detected that the sign of the first supply power value is not appropriate, the correction unit stores the correction unit in the storage unit during a period from the measurement start time until it is detected that the sign is not appropriate. When the sign of the written first supply power value is changed to the opposite sign, and it is detected that the sign of the second supply power value is not appropriate, the sign is changed from the measurement start time. 4. The power measurement according to claim 1, wherein the sign of the second supply power value written in the storage unit is changed to an opposite sign in a period until it is detected that it is not appropriate. apparatus.   When the sign control unit detects that the sign of the supply power value is not appropriate based on the comparison between the supply power value and the generated power value, it outputs an inappropriate signal indicating that the sign is not appropriate. And a flip-flop circuit for starting output of a control signal for controlling the sign of the supply power value to be opposite to that of the supply power value when the inappropriate signal is output. The power measuring apparatus according to claim 4.   The power measuring device according to any one of claims 1 to 5, further comprising the main-side current sensor, the sub-side current sensor, and the voltage sensor.   The power measuring device according to any one of claims 1 to 6, further comprising a display unit that displays that a sign of the supplied power value stored in the storage unit is corrected. The current value output by the main-side current sensor that detects the current value of the current flowing through the path portion on the main power generator side of the load in the connection path that electrically connects the main power generator and the sub power generator via the load And based on the voltage value output from the voltage sensor that detects the voltage value of the connection path, the power value of the power supplied from the main power generation device to the load is calculated as the supply power value,
Based on the current value output by the sub-side current sensor that detects the current value of the current flowing in the path portion on the sub power generator side of the load in the connection path, and the voltage value output by the voltage sensor, Calculate the power value of the power output from the sub power generator as the generated power value,
The calculated supply power value and the generated power value are stored in an internal or external storage unit in a manner associated with time information indicating the time when the voltage value and the current value used for calculation are detected, respectively. writing,
When the supply power value and the generated power value are used to detect that the sign of the supply power value is not appropriate, control is performed so that the calculated sign of the supply power value is reversed. And
When it is detected that the sign of the supplied power value is not appropriate, it is detected that the sign is not appropriate from the measurement start time based on the measurement start time information acquired when the power measurement is started. A power measurement method for changing the sign of the supplied power value written in the storage unit to a reverse sign in a period until the first time.

Images