JP2000009757A - Demand monitoring device - Google Patents

Abstract

(57) [Summary] [Problem] It is not necessary to use a power meter pulse input of a watt hour meter with a transmitting device for an electric power company or an existing watt hour meter with a transmitting device, or to require a watt hour meter with a transmitting device Even in such a case, it is an object of the present invention to provide a demand monitoring device that can flexibly cope with the same equipment in various situations according to the actual conditions of the equipment. SOLUTION: External pulse input measuring means for measuring an electric energy by inputting an electric energy pulse output from a watt hour meter 4 with a transmitting device, and high-voltage internal measuring means for measuring an electric energy from a voltage and a current on a high voltage side. And an electric energy metering selecting means 10 for selecting one of the two means, and a demand electric power calculating means 11 for performing a demand electric power calculation from the electric power measuring value selected by the electric energy measuring and selecting means 10. Have.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a demand monitoring device for calculating a demand power from a power amount.

[0002]

2. Description of the Related Art Conventionally, demand monitoring has been performed as shown in FIG. In FIG. 5, reference numeral 72 denotes a transformer, 73 denotes an instrument transformer (hereinafter, referred to as PT), and 74 denotes a current transformer (hereinafter, referred to as CT), all of which are connected to an AC power line. 75 is a watt-hour meter with a transmitter connected to the outputs of the PT 73 and CT 74, and 76 is a watt-hour meter with a transmitter 75
Is an electric energy pulse input unit connected to the output of the electric energy pulse input measuring unit 77 connected to the output of the electric energy pulse input unit 76, and 78 is a demand electric power calculating means connected to the output of the electric energy pulse input measuring unit 77. , The electric energy pulse input unit 76,
The power amount pulse input metering unit 77 and the demand power calculation means 78 constitute a demand monitoring device.

[0003] In this configuration, a watt-hour meter 75 with a transmitter measures a power amount based on a voltage input from the PT 73 and a current input from the CT 74, outputs a pulse corresponding to the power amount, and outputs the power amount pulse on demand. The received power is calculated by the monitoring device, and demand monitoring is performed. In the demand monitoring device, the electric energy pulse output from the electric energy meter 75 with the transmitting device is received by the electric energy pulse input unit 76 and the electric energy is measured by the electric energy pulse input measuring unit 77.
The demand power calculation means 78 performs a demand power calculation from the power measured by the power pulse input measuring unit 77.

[0004]

However, in the above-mentioned conventional configuration, the electric energy pulse from the electric meter with the transmitting device or the electric meter with the transmitting device for the electric power company (not shown) is directly or pulsed. Generally, the data is input to the demand monitoring device via a receiving device (not shown).

[0005] For this reason, there is no problem in using the electric energy pulse input of the electric energy meter with the transmitting device for the transaction of the electric power company or the existing electric energy meter 75 with the transmitting device, but the electric energy meter with the transmitting device is required. In the case where it is not necessary, or even when PT and CT are not required on the high pressure side, the same configuration as described above must be adopted, and there is a problem that it is not possible to flexibly respond to the actual conditions of equipment in various situations. I was

[0006] The present invention solves the above-mentioned conventional problems, and is applicable to a case where an electric energy pulse input is used, a case where a power meter with a transmitter is not required, and a case where PT and CT are not required. It is another object of the present invention to provide a demand monitoring device having the same configuration and capable of flexibly responding to various types of equipment.

[0007]

According to a first aspect of the present invention, there is provided a demand monitoring apparatus comprising: an external pulse input measuring means for measuring an electric energy by inputting an electric energy pulse output from a watt hour meter with a transmitting device; High-voltage internal metering means for measuring the electric energy from the voltage and the current, electric power metering selecting means for selecting one of the external pulse input measuring means and the high-voltage internal measuring means, and electric power metering selecting means. Demand power calculation means for performing a demand power calculation from the measured power value.

According to the demand monitoring device of the first aspect, one of the external pulse input measuring means and the high voltage internal measuring means is selected by the electric energy metering selecting means to perform the demand power calculation. In the example of selecting the pulse input metering means, as one of the operations, it is possible to use the pulse input of a watt hour meter with a transmitter for transaction of a power company,
Therefore, management without a difference from a transaction meter can be performed. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy. Second
In the example where the high pressure internal weighing means is selected, the high pressure PT, C
It is necessary to input a voltage and a current from T. In this case, however, it is not necessary to separately provide a wattmeter with an external transmitter. In this way, any one of the electric energy metering means can be selected by the electric energy metering selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the actual situation of the equipment in various situations described above.

According to a second aspect of the present invention, there is provided a demand monitoring apparatus, comprising: an external pulse input measuring means for measuring an electric energy by inputting an electric energy pulse output from a watt hour meter with a transmitting device; The internal power of each feeder power amount from the current and the low voltage power amount total measuring means for measuring the power amount by summing all the feeder power amounts, and the external pulse input measuring means and the low voltage power amount total measuring means. The electric power meter includes a power amount measurement selecting means for selecting one, and a demand power calculating means for performing a demand power calculation from the power measured value selected by the power amount measuring selecting means.

According to the demand monitoring device of the present invention, the demand power calculation is performed by selecting the external pulse input measuring means or the low-voltage power amount total measuring means by the power amount measuring selecting means. In the example of selecting the input metering means, as one of the operations, it is possible to use the pulse input of a watt hour meter with a transaction transmitting device of a power company,
Therefore, management without a difference from a transaction meter can be performed. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy. Second
In the example in which the low-voltage power amount total measuring means is selected, since the power amount of each low-voltage feeder is measured and the total power amount of the feeder is measured, PT and CT on the high-voltage side are unnecessary. In this way, any one of the electric energy metering means can be selected by the electric energy metering selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the actual situation of the equipment in various situations described above.

According to a third aspect of the present invention, there is provided a demand monitoring device, comprising: a high voltage internal measuring means for measuring an electric energy from a voltage and a current on a high voltage side; A low-voltage power amount total measuring means for measuring the power amount by measuring the total amount of the feeder power amounts; and a power amount measuring selecting means for selecting one of the high-voltage internal measuring means and the low-voltage power amount total measuring means. And a demand power calculating means for performing a demand power calculation from the measured value of the power selected by the power metering selecting means.

According to the demand monitoring device of the third aspect, the high-voltage internal metering means or the low-voltage power amount total metering means is selected by the electric energy metering selecting means to perform the demand power calculation. In the example of selecting the means, it is necessary to input the voltage and the current from the high-voltage PT and CT. In this case, however, it is not necessary to separately provide an external watt-hour meter with a transmitter. Secondly, in the example in which the low-voltage power amount total measuring means is selected, the power amount of each low-voltage feeder is measured and the total power amount of the feeder is measured.
This eliminates the need for CT. In this way, any of the electric energy metering means is selected by the electric energy metering selecting means, and
Since demand monitoring can be performed with a model demand monitoring device,
It is possible to flexibly respond to the actual conditions of the equipment in the various situations described above.

According to a fourth aspect of the present invention, there is provided a demand monitoring device, comprising: an external pulse input measuring means for inputting a power amount pulse output from a watt-hour meter provided with a transmitting device and measuring the power amount; A high-pressure internal metering means for measuring the amount, and a low-voltage power amount summation for measuring the power amount by internally measuring each feeder power amount from the voltages and currents of all the feeders on the low-pressure side and summing up the feeder power amounts. Metering means, power metering selecting means for selecting any one of the external pulse input metering means, high voltage internal metering means and low voltage power metering metering means, and power selected by the power metering selecting means And a demand power calculation means for performing a demand power calculation from the weighed value.

According to the demand monitoring device of claim 4, any one of the external pulse input measuring means, the high voltage internal measuring means, and the low voltage electric energy total measuring means is selected by the electric energy measuring selecting means, and the demand electric power is measured. To perform the operation, the first
In the example where the external pulse input measuring means is selected,
First, it is possible to use the pulse input of a watt-hour meter with a power transmitting device of a power company, and therefore, it is possible to perform management without difference from a transaction meter. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy. Second, in the example of selecting the high-pressure internal metering means, it is necessary to input a voltage and a current from the high-voltage PT and CT, but in this case, a separate external watt hour meter with a transmitter is not required. Thirdly, in the example of selecting the low-voltage power amount total measuring means, the power amount of each low-voltage feeder is measured and the total power amount of the feeder is measured, so that the PT and CT on the high voltage side are not required. is there. As described above, any of the power amount measuring means can be selected by the power amount measuring and selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the above-mentioned various actual situations of the equipment.

[0015]

Embodiments of the present invention will be described below. (First Embodiment) A first embodiment of the present invention will be described with reference to FIG. In FIG. 1, reference numeral 1 denotes a transformer connected to an AC circuit, and a transformer for an instrument (hereinafter, referred to as PT) 2 and a current transformer (hereinafter, referred to as CT) 3 are connected to the AC circuit on the high voltage side of the transformer 1. Have been.

Reference numeral 4 denotes a watt hour meter with a transmitter connected to the secondary side of PT2, 5 denotes a power pulse input unit connected to the output of the watt meter 4 with the transmitter, and 6 denotes an output of a power pulse input unit 5. PT2, C
An external pulse input measuring means is constituted by T3, a watt hour meter with a transmitting device, a power amount pulse input section 5, and a power amount pulse input measuring section 6.

7 is a voltage input section connected to the secondary side of PT2, 8 is a current input section connected to the output of CT3, 9 is an internal measuring section connected to the respective outputs of the voltage input section 7 and the current input section 8. Thus, PT2, CT3, voltage input unit 7, current input unit 8, and internal weighing unit 9 constitute high-pressure internal weighing means. Reference numeral 10 denotes an electric energy metering selection unit that connects the output of the electric energy pulse input measuring unit 6 and the output of the internal measuring unit 9.
Reference numeral 11 denotes a demand power calculation unit connected to the output of the power amount measurement selection unit 10.

Here, the power amount pulse input unit 5, the power amount pulse input metering unit 6, the voltage input unit 7, the current input unit 8, the internal metering unit 9, the power amount metering selection unit 10 and the demand power calculating unit 11 make the demand. Configures a monitoring device. The operation of the demand monitoring device configured as described above will be described with reference to FIG. First, only one of the external pulse input measuring means and the high voltage internal measuring means is selected by the electric energy measuring and selecting means 10.

When the external pulse input measuring means is selected by the electric energy measuring and selecting means 10, the voltage from the high-voltage PT2 and the current from the high-voltage CT3 are input to the watt-hour meter 4 with the transmitting device, and The electric energy is measured by the meter 4 and the measured value is transmitted as an electric energy pulse, and the electric energy pulse is input to the electric energy pulse input unit 5 of the demand monitoring device. The input electric energy pulse is multiplied by a pulse constant for each pulse in the electric energy pulse input measuring unit 6,
Measure the amount of power. Further, a pulse receiving device may be provided between the watt hour meter 4 with the transmitting device and the demand monitoring device. In this method, it is possible to use the pulse input of a watt hour meter with a transmitter for mounting of a power company, and therefore, it is possible to perform management without difference from a transaction meter. In addition, if there is an existing watt hour meter with a transmitter, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

When the high-voltage internal metering means is selected by the electric energy metering selecting means 10, the voltage from the high-voltage PT2 and the high-voltage C
The current from T3 is directly input to the voltage input unit 7 and the current input unit 8 of the demand monitoring device without passing through the watt hour meter 4 with the transmitting device. The internal measuring unit 9 measures the electric power from the waveform input of the voltage and the current and measures the electric energy. In this system, it is necessary to input a voltage and a current from the high-voltage PT and CT. In this case, however, it is not necessary to separately provide a wattmeter with an external transmitter.

Further, since demand power calculation is performed by the demand power calculation means 11 from the measured value of the power quantity selected by the power quantity measurement selection means 10, any power quantity measurement means is selected by the power quantity measurement selection means 10. Thus, demand monitoring can be performed by one type of demand monitoring device.
For this reason, it can respond flexibly according to various equipment actual conditions.

The same effect can be obtained even if a pulse receiving device is connected between the watt-hour meter 4 with the transmitting device and the demand monitoring device. (Embodiment 2) A second embodiment of the present invention will be described with reference to FIG. In FIG. 2, reference numeral 12 denotes a transformer connected to an AC circuit. An AC transformer on the high-voltage side of the transformer 12 includes an instrumentation transformer (hereinafter, referred to as PT) 13 and a current transformer (hereinafter, referred to as PT).
CT 14) is connected.

Reference numeral 15 denotes a watt hour meter with a transmitter connected to the secondary side of the PT 13, reference numeral 16 denotes a power pulse input unit connected to the output of the watt meter 15 with the transmitter, and reference numeral 17 denotes an output of the power pulse input unit 16. , PT13, CT14, watt-hour meter with transmitter 15,
The power pulse input unit 16 and the power pulse input measuring unit 17 constitute an external pulse input measuring unit.

Further, a circuit via PT18, CT19 and PT20, CT2
Two circuits are connected through the circuit 1. 22 is PT
A feeder voltage input unit 23 connected to the secondary side of the feeder unit 18 is a feeder current input unit connected to the output of the CT 19. The output of the feeder voltage input unit 22 is connected to the feeder current input unit 23.
Is connected to the feeder power amount measuring unit 26. Reference numeral 24 denotes a feeder voltage input unit connected to the secondary side of the PT 20, and reference numeral 25 denotes a feeder current input unit connected to the output of the CT 21, and the outputs of the feeder voltage input unit 24 and the feeder current input unit 25 are feeder power. It is connected to the quantity measuring section 27.

The outputs of the feeder power metering section 26 and the feeder power metering section 27 are connected to a low-voltage power metering and metering section 28, and PT18, CT19, PT2.
0, CT 21, feeder voltage input unit 22, feeder current input unit 23, feeder power amount measuring unit 26, feeder voltage input unit 24, feeder current input unit 25, feeder power amount measuring unit 27, and low-voltage power amount summing unit 28. It constitutes a low voltage electric energy summation measuring means.

Reference numeral 29 denotes an electric energy pulse input measuring section 17.
Is an electric energy metering selecting means connected to the output of the low voltage electric energy total measuring section 28, and 30 is a demand electric power calculating means connected to the output of the electric energy measuring selecting section 29. Pulse input metering unit 17, feeder voltage input unit 22, feeder current input unit 23, feeder power amount measuring unit 26, feeder voltage input unit 24, feeder current input unit 25, feeder power amount measuring unit 27, low voltage power amount summing unit 28, a power metering selection unit 29 and a demand power calculation unit 30 constitute a demand monitoring device.

The operation of the demand monitoring device configured as described above will be described with reference to FIG. First, only one of the external pulse input measuring means and the low-voltage electric energy total measuring means is selected by the electric energy measuring and selecting means 29.
When the external pulse input measurement means is selected by the electric energy measurement selection means 29, the voltage from the high-pressure PT13 and the high-voltage CT1
4 is input to the watt-hour meter 15 with the transmitting device, and the power amount is measured by the watt-hour meter 15 with the transmitting device.
The measured value is transmitted as a power amount pulse, and the power amount pulse is input to the power amount pulse input unit 16 of the demand monitoring device. The input electric energy pulse is multiplied by a pulse constant for each pulse in an electric energy pulse input measuring unit 17,
Measure the amount of power. Further, a pulse receiving device may be provided between the watt hour meter 15 with the transmitting device and the demand monitoring device. In this method, it is possible to use the pulse input of a watt hour meter with a transmitter for mounting of a power company, and therefore, it is possible to perform management without difference from a transaction meter. In addition, if there is an existing watt hour meter with a transmitter, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

When the low-voltage power-sum total measuring means is selected by the power-measurement selecting means 29, for example, in the case of a low-voltage two-circuit,
In the first circuit, the voltage from the low voltage PT18 and the low voltage CT1
9 is input to the feeder voltage input section 22 and the feeder current input section 23 of the demand monitoring device, respectively. In the second circuit, the voltage from the low-voltage PT 20 and the low-voltage C
The current from T21 is input to the feeder voltage input unit 24 and the feeder current input unit 25 of the demand monitoring device. The feeder power metering unit 26 measures the feeder power from the input of the voltage and current waveforms of the first circuit, and measures the feeder power. The feeder power metering section 27 performs the second circuit in the same manner as described above. The feeder power amounts measured by the feeder power amount measuring units 26 and 27 are all summed up by a low-voltage power amount summing and measuring unit 28, and are measured as electric power amounts. In this method, the electric energy of each low-pressure feeder is measured and the total electric power of the feeder is measured, so that the PT and CT on the high voltage side are not required.

Further, since demand power calculation is performed by the demand power calculation means 30 from the measurement value of only one power quantity selected by the power quantity measurement selection means 29, any of the power quantity measurement means selects the power quantity measurement. The demand monitoring can be performed by a single type of demand monitoring device selected by the means 29. For this reason, it can respond flexibly according to various equipment actual conditions.

Note that a pulse receiving device may be provided between the watt-hour meter 15 with the transmitting device and the demand monitoring device.
Further, the number of branch circuits at low voltage may be any number. (Embodiment 3) A third embodiment of the present invention will be described with reference to FIG. In FIG. 3, reference numeral 31 denotes a transformer connected to an AC circuit, and an AC transformer on the high voltage side of the transformer 1 includes a meter transformer (hereinafter, referred to as PT) 32 and a current transformer (hereinafter, C).
T) 33 is connected.

Reference numeral 34 denotes a voltage input section connected to the secondary side of the PT 32; 35, a current input section connected to the output of the CT 33;
Reference numeral 6 denotes an internal weighing unit connected to the outputs of the voltage input unit 34 and the current input unit 35, and includes PT32, CT33, the voltage input unit 34,
The current input unit 35 and the internal measuring unit 36 constitute a high-pressure internal measuring unit. Further, a circuit via PT37 and CT38 and a PT
Two circuits 39 and CT40 are connected.

Reference numeral 41 denotes a feeder voltage input unit connected to the secondary side of the PT 37, and reference numeral 42 denotes a feeder current input unit connected to the output of the CT 38. The output of the feeder voltage input unit 41 and the output of the feeder current input unit 42 are It is connected to the feeder electric energy meter 45. Reference numeral 43 denotes a feeder voltage input unit connected to the secondary side of the PT 39, reference numeral 44 denotes a feeder current input unit connected to the output of the CT 40, and the output of the feeder voltage input unit 43 and the output of the feeder current input unit 44 are feeder It is connected to the electric energy meter 46.

Then, the feeder electric energy measuring units 45 and 46
Are connected to a low voltage electric energy summing and measuring unit 47, and are connected to PT37, CT38, and feeder voltage input unit 4.
1, feeder current input unit 42, feeder power amount measuring unit 4
5, a PT 39, a CT 40, a feeder voltage input section 43, a feeder current input section 44, a feeder power amount measuring section 46 and a low voltage power amount total measuring section 47 constitute a low voltage power total measuring section.

Numeral 48 denotes an electric energy metering selecting means which connects the output of the internal metering section 36 and the output of the low voltage electric energy total metering section 47, and 49 denotes a demand electric power calculating means which connects the output of the electric energy metering selecting means 48. Yes, voltage input section 34, current input section 35, internal metering section 36, feeder voltage input section 41,
A feeder current input section 42, a feeder power amount measuring section 45,
A feeder voltage input unit 43, a feeder current input unit 44, a feeder power amount measuring unit 46, a low-voltage power amount total measuring unit 47,
Electricity metering selecting means 48 and demand power calculating means 4
9 constitutes a demand monitoring device.

The operation of the demand monitoring device configured as described above will be described with reference to FIG. First, only one of the high-voltage internal measuring means and the low-voltage electric energy total measuring means is selected by the electric energy measuring and selecting means 48. When the high voltage internal metering means is selected by the electric energy metering selecting means 48,
The voltage from the high-voltage PT 32 and the current from the high-voltage CT 33 are directly input to the voltage input unit 34 and the current input unit 35 of the demand monitoring device without passing through the watt-hour meter with the transmitter. The internal measuring unit 36 measures the electric power from the waveform input of the voltage and the current and measures the electric energy. In this system, it is necessary to input a voltage and a current from the high-voltage PT and CT. In this case, however, it is not necessary to separately provide a wattmeter with an external transmitter.

When the low-voltage electric power summing and measuring means is selected by the electric energy measuring and selecting means 48, for example, in the case of two low-voltage circuits,
In the first circuit, the voltage from the low voltage PT37 and the low voltage CT3
8 is input to the feeder voltage input unit 41 and the feeder current input unit 42 of the demand monitoring device, respectively. In the second circuit, the voltage from the low-voltage PT 39 and the low-voltage C
The current from T40 is input to the feeder voltage input unit 43 and the feeder current input unit 44 of the demand monitoring device. The feeder power metering unit 45 measures the feeder power from the input of the voltage and current waveforms of the first circuit, and measures the feeder power. The second circuit is performed in the feeder power amount measuring section 46 in the same manner as described above. The feeder power amounts measured by the feeder power amount measuring units 45 and 46 are all summed up by the low-voltage power amount summing and measuring unit 47, and are measured as the power amount. In this method, the electric energy of each low-pressure feeder is measured and the total electric power of the feeder is measured, so that the PT and CT on the high voltage side are not required.

Further, the electric energy metering means selecting means 48 selects 1
Since demand power calculation is performed by the demand power calculation means 49 from the measured values of only one power quantity, any one of the power quantity measurement means is selected by the power quantity measurement selection means 48 and demand is calculated by one type of demand monitoring device. Monitoring can be performed. For this reason, it can respond flexibly according to various equipment actual conditions.

The number of branch circuits at low voltage may be any number. (Embodiment 4) A fourth embodiment of the present invention will be described with reference to FIG. In FIG. 4, reference numeral 50 denotes a transformer connected to an AC circuit, and a high-voltage side AC circuit of the transformer 50 includes an instrumentation transformer (hereinafter, referred to as PT) 51 and a current transformer (hereinafter, referred to as PT).
CT) 52 are connected.

Reference numeral 53 denotes a watt hour meter with a transmitter connected to the secondary side of PT2; 54, a power pulse input unit connected to the output of the watt meter 53 with the transmitter; 55, an output of the power pulse input unit 54; In the electric energy pulse input measuring section connected to
The external pulse input measuring means is constituted by the PT 51, the CT 52, the watt-hour meter 53 with the transmitting device, the power amount pulse input section 54, and the power amount pulse input measuring section 55.

Reference numeral 56 denotes a voltage input section connected to the secondary side of the PT 51; 57, a current input section connected to the output of the CT 52;
Reference numeral 8 denotes an internal weighing unit that connects the respective outputs of the voltage input unit 56 and the current input unit 57. The internal weighing unit is constituted by PT51, CT52, the voltage input unit 56, the current input unit 57, and the internal weighing unit 58. I have. Transformer 5
Two circuits, a circuit via PT59 and CT60 and a circuit via PT61 and CT62, are connected to the low-voltage side AC circuit of 0.

Reference numeral 63 denotes a feeder voltage input unit connected to the secondary side of the PT 59, and 64 denotes a feeder current input unit connected to the output of the CT 60. The output of the feeder voltage input unit 63 and the output of the feeder current input unit 64 are connected to each other. Is connected to the feeder power amount measuring unit 67. 65 is a feeder voltage input section connected to the secondary side of the PT 61, 66 is a feeder current input section connected to the output of the CT 62, and the outputs of the feeder voltage input section 65 and the feeder current input section 66 are feeder power. It is connected to the quantity measuring section 68.

The outputs of the feeder power metering section 67 and the feeder power metering section 68 are connected to a low-voltage power metering and metering section 69, and are connected to PT59, CT60, PT6.
1, a CT 62, a feeder voltage input unit 63, a feeder current input unit 64, a feeder power amount measuring unit 67, a feeder voltage input unit 65, a feeder current input unit 66, a feeder power amount measuring unit 68, and a low-voltage power amount summing unit 69. It constitutes a low voltage electric energy summation measuring means.

Reference numeral 70 denotes an electric energy pulse input measuring section 55.
, An output of the internal weighing unit 58 and an output of the low-voltage power summing and weighing unit 69 are connected. A demand power calculating unit 71 is connected to an output of the power weighing selection unit 70. A pulse input unit 54, an electric energy pulse input measuring unit 55, a voltage input unit 56, a current input unit 57,
Internal metering section 58, feeder voltage input section 63, feeder current input section 64, feeder power amount measuring section 67, feeder voltage input section 65, feeder current input section 66, feeder power amount measuring section 68, low-voltage power amount total measuring section 69. , The power metering selection means 70 and the demand power calculation means 71 constitute a demand monitoring device.

The operation of the demand monitoring device configured as described above will be described with reference to FIG. First, only one of the external pulse input measuring means, the high voltage internal measuring means, and the low voltage electric energy total measuring means is selected by the electric energy measuring and selecting means 70. When the external pulse input measuring means is selected by the electric energy metering selecting means 70, the voltage from the high voltage PT 51 and the current from the high voltage CT 52 are input to the electric energy meter 53 with the transmitting device, and the electric energy meter 53 with the transmitting device is inputted. , And the measured value is transmitted as a power amount pulse, and the power amount pulse is input to the power amount pulse input unit 54 of the demand monitoring device. The input electric energy pulse is multiplied by a pulse constant for each pulse in an electric energy pulse input measuring section 55 to measure the electric energy. Alternatively, a pulse receiving device may be provided between the watt-hour meter 53 with the transmitting device and the demand monitoring device. In this method, it is possible to use the pulse input of a watt hour meter with a transmitter for mounting of a power company, and therefore, it is possible to perform management without difference from a transaction meter. In addition, if there is an existing watt hour meter with a transmitter, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

When the high-voltage internal measuring means is selected by the electric-power-measuring selecting means 70, the voltage from the high-voltage PT 51 and the current from the high-voltage CT 52 do not pass through the watt-hour meter 53 with the transmitting device, but are directly connected to the demand monitoring device. Are input to the voltage input unit 56 and the current input unit 57, respectively. The internal measuring unit 58 measures the power from the waveform input of the voltage and the current, and measures the power amount. In this system, it is necessary to input a voltage and a current from the high-voltage PT and CT. In this case, however, it is not necessary to separately provide a wattmeter with an external transmitter.

When the low-voltage power-sum total measuring means is selected by the electric-power-measuring selecting means 70, for example, in the case of two low-voltage circuits,
In the first circuit, the voltage from the low voltage PT59 and the low voltage CT6
The current from 0 is input to the feeder voltage input unit 63 and the feeder current input unit 64 of the demand monitoring device, respectively. In the second circuit, the voltage from the low-voltage PT 61 and the low-voltage C
The current from T62 is input to the feeder voltage input unit 65 and the feeder current input unit 66 of the demand monitoring device. The feeder power metering section 67 measures the feeder power from the voltage and current waveform inputs of the first circuit, and measures the feeder power. The second circuit is performed by the feeder power amount measuring section 68 in the same manner as described above. The feeder power amounts measured by the feeder power amount measuring units 67 and 68 are all summed up by the low-voltage power amount totaling and measuring unit 69, and are measured as the power amount. In this method, the electric energy of each low-pressure feeder is measured and the total electric power of the feeder is measured, so that the PT and CT on the high voltage side are not required.

Further, since the demand power calculation is performed by the demand power calculating means 71 from the measured value of the power quantity selected only by the power quantity measuring and selecting means 70, any power quantity measuring means can be used. Since demand monitoring can be performed by one type of demand monitoring device selected by the user 70, it is possible to flexibly respond to equipment actual conditions in various situations.

Note that a pulse receiving device may be provided between the watt-hour meter 53 with the transmitting device and the demand monitoring device.
Further, the number of branch circuits at low voltage may be any number.

[0049]

According to the demand monitoring apparatus of the first aspect, the following excellent effects can be obtained by providing two means for measuring the amount of power and the means for selecting and measuring the amount of power. First, in the example of selecting the external pulse input measuring means,
As one of the operations, it is possible to use the pulse input of a watt hour meter with a transmitting device of a power company, and therefore, it is possible to perform management without difference from a trading meter. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

Second, in the example of selecting the high-pressure internal metering means, it is necessary to input the voltage and current from the high-voltage PT and CT. In this case, however, there is no need for a separate external watt-hour meter with a transmitter. As described above, any one of the power amount measuring means can be selected by the power amount measuring selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the above-mentioned various situations of the equipment. It has an excellent effect.

According to the demand monitoring device of the second aspect, the following excellent effects can be obtained by providing two means for measuring the amount of power and the means for selecting and measuring the amount of power. First, in the example of selecting the external pulse input measuring means,
As one of the operations, it is possible to use the pulse input of a watt hour meter with a transmitting device of a power company, and therefore, it is possible to perform management without difference from a trading meter. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

Secondly, in the example of selecting the low-voltage electric energy summing and measuring means, the electric energy of each low-voltage feeder is measured, and the total electric power of the feeder is measured.
This eliminates the need for T and CT. As described above, any one of the power amount measuring means can be selected by the power amount measuring selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the above-mentioned various situations of the equipment. It has an excellent effect.

According to the demand monitoring device of the third aspect, the following excellent effects can be obtained by providing the two power amount measuring means and the power amount measuring selecting means. First, in the example in which the high-pressure internal metering means is selected, it is necessary to input a voltage and a current from the high-voltage PT and CT, but in this case, a separate external watt-hour wattmeter with a transmitter is not required.

Secondly, in the example of selecting the low-voltage power amount total measuring means, the power amount of each low-voltage feeder is measured and the total power amount of the feeder is measured.
This eliminates the need for T and CT. As described above, any one of the power amount measuring means can be selected by the power amount measuring selecting means and demand monitoring can be performed by one type of demand monitoring device, so that it is possible to flexibly cope with the above-mentioned various situations of the equipment. It has an excellent effect.

According to the demand monitoring device of the fourth aspect, the following excellent effects can be obtained by providing the three power amount measuring means and the power amount measuring and selecting means. First, in the example of selecting the external pulse input measuring means,
As one of the operations, it is possible to use the pulse input of a watt hour meter with a transmitting device of a power company, and therefore, it is possible to perform management without difference from a trading meter. As another operation, if there is an existing watt-hour meter with a transmitting device, only the pulse is input, so that the input wiring requires only two-core input wires, and installation is easy.

Second, in the case of selecting the high-pressure internal metering means, it is necessary to input the voltage and current from the high-pressure PT and CT. In this case, however, it is not necessary to separately provide an external wattmeter with a transmitter. Thirdly, in the example of selecting the low-voltage power amount total measuring means, the power amount of each low-voltage feeder is measured and the total power amount of the feeder is measured, so that the PT and CT on the high voltage side are not required. is there.

As described above, any one of the electric energy metering means can be selected by the electric energy metering selecting means and the demand can be monitored by one type of demand monitoring device. It has excellent effects that can be handled.

[Brief description of the drawings]

FIG. 1 is a block diagram of a demand monitoring device according to a first embodiment of the present invention.

FIG. 2 is a block diagram of a demand monitoring device according to a second embodiment of the present invention.

FIG. 3 is a block diagram of a demand monitoring device according to a third embodiment of the present invention.

FIG. 4 is a block diagram of a demand monitoring device according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram of a conventional demand monitoring device.

[Explanation of symbols]

1, 12, 31, 50 Transformers 2, 13, 18, 20, 32, 37, 39, 51, 5
9,61 Instrument transformer (PT) 3,14,19,21,33,38,40,52,6
0,62 Current transformer (CT) 4,15,53 Watt hour meter with transmitting device 5,16,54 Power amount pulse input unit 6,17,55 Power amount pulse input measuring unit 7,34,56 Voltage input unit 8 , 35, 57 Current input unit 9, 36, 58 Internal metering unit 10, 29, 48, 70 Electricity metering selecting unit 11, 30, 49, 71 Demand power calculating unit 22, 24, 41, 43, 63, 65 Feeder Voltage input unit 23, 25, 42, 44, 64, 66 Feeder current input unit 26, 27, 45, 46, 67, 68 Feeder electric energy metering unit 28, 47, 69 Low voltage electric energy total metering unit

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Tomohiro Fujii 1006 Kazuma Kadoma, Kadoma City, Osaka F-term in Matsushita Electric Industrial Co., Ltd. 5G066 KA01 KA11 KA12

Claims (4)

[Claims] 1. An external pulse input measuring means for inputting a power amount pulse output from a watt hour meter with a transmitting device and measuring an electric power amount, and a high voltage internal measuring means for measuring an electric power amount from a voltage and a current on a high voltage side. An electric energy metering selecting means for selecting one of the external pulse input measuring means and the high voltage internal metering means; and a demand electric power operation for calculating a demand electric power from the electric power measuring value selected by the electric energy measuring and selecting means. Demand monitoring device provided with means. 2. An external pulse input measuring means for inputting a power amount pulse output from a watt-hour meter provided with a transmitting device and measuring the power amount, and calculating each feeder power amount from voltages and currents of all feeders on the low voltage side. A low-voltage power totaling and metering unit that measures the amount of power by internally measuring and adding up all of the feeder power amounts, and a power amount meter that selects one of the external pulse input measuring unit and the low-voltage power totaling and metering unit. A demand monitoring device, comprising: a selection unit; and a demand power calculation unit that calculates a demand power from a measured value of the power selected by the power amount measurement selection unit. 3. A high-pressure internal metering means for measuring an electric energy from a voltage and a current on a high-voltage side, and an internal measuring means for each feeder electric energy from voltages and currents of all feeders on a low-voltage side. A low-voltage electric energy summing and measuring means for measuring the electric energy by adding them all together; an electric energy measuring and selecting means for selecting one of the high-pressure internal measuring means and the low-voltage electric energy summing and measuring means; A demand power calculating means for performing a demand power calculation from a measured value of the power selected by the above. 4. An external pulse input measuring means for measuring an electric energy by inputting an electric energy pulse output from a watt-hour meter with a transmitting device, and a high-voltage internal measuring means for measuring an electric energy from a voltage and a current on a high voltage side. And a low-voltage power amount total measuring means for measuring the power amount by internally measuring each feeder power amount from the voltage and current of all the low-voltage side feeders, and the external pulse input. Measuring means,
An electric energy metering selecting means for selecting any one of the high voltage internal metering means and the low voltage electric energy summing metering means, and a demand electric power for performing a demand electric power calculation from the electric power measuring value selected by the electric energy metering selecting means A demand monitoring device comprising a calculating means.