JP7444002B2 - Judgment device and program - Google Patents

Description

The present invention relates to a determination device and a program.

Traditionally, power supplied by high voltage distribution lines is converted to low voltage using pole transformers. For example, 6600V power supplied by a high voltage distribution line is converted to a low voltage of 100V using a pole transformer. The low voltage side of the pole transformer is connected to the low voltage line. The low-voltage lines are installed up to the utility poles (hereinafter referred to as terminal poles) that are connected to service lines for each home. Devices for stably supplying power using such high-voltage distribution lines, pole transformers, and low-voltage lines have been proposed (see, for example, Patent Documents 1 and 2).

JP 2019-154133 Publication Japanese Patent Application Publication No. 2012-237573

Patent Document 1 discloses that the voltage of a high-voltage line is determined using the voltage value and current value of a smart meter connected to the secondary side of a transformer and the impedance of a drop-in line. Patent Document 2 discloses calculating the impedance of a low-voltage distribution line in order to calculate the voltage drop of the low-voltage distribution line to which a plurality of loads are connected.

By the way, as described in Patent Document 2, a plurality of drop-in lines are connected to the low-voltage line. Therefore, when a new drop-in line is connected to the low-voltage line at the terminal pole, a voltage drop occurs in the low-voltage line from the connection point to the pole transformer to the terminal pole in response to the increased load. Therefore, conventionally, when a voltage drop exceeding a predetermined value occurs, the low-voltage line is rewired (for example, replaced with a wire with a larger diameter). On the other hand, since relining work for low-voltage lines is costly, it is preferable to optimize the implementation of relining work while ensuring safety.

In view of the above-mentioned problems, an object of the present invention is to provide a determination device and a program capable of optimizing implementation of low-voltage line replacement work.

The present invention provides a judgment device that determines whether or not a low voltage line placed between a pole transformer and a service line needs to be replaced in accordance with the addition of a load. A first terminal voltage acquisition section that obtains the terminal voltage of the side as the first terminal voltage, and a first voltage drop calculation section that calculates the voltage value dropped in the low voltage line before the expansion as the first voltage drop, are added. a second voltage drop calculation unit that calculates a voltage value that drops in the low-voltage line after expansion as a second voltage drop based on the load; and a second voltage drop calculation unit that calculates the first terminal voltage, the first voltage drop, and the second voltage drop. a second terminal voltage calculation unit that calculates, based on the voltage, a terminal voltage on the drop-in line side of the low-voltage line after load addition as a second terminal voltage; The present invention relates to a determination device including a determination unit that determines whether reupholstery is necessary.

Further, it is preferable that the determination unit determines whether or not the low-voltage line needs to be replaced, based on whether the second terminal voltage can maintain a predetermined standard voltage.

Further, the second terminal voltage calculation unit includes:
(The first terminal voltage)-{(the second voltage drop)-(the first voltage drop)}
It is preferable to calculate the second terminal voltage by calculating .

Further, it is preferable that the second voltage drop calculation unit determines whether or not the low-voltage line needs to be replaced based on a voltage drop during a season when power consumption is at its peak.

The present invention also provides a program that causes a computer to function as a determination device that determines whether or not a low-voltage line placed between a pole transformer and a service line needs to be rewired in response to an increase in load, the program comprising: A first terminal voltage acquisition unit that acquires a terminal voltage on the drop-in line side of the low-voltage line before expansion as a first terminal voltage, and acquires a voltage value dropped in the low-voltage line before expansion as a first voltage drop. a first voltage drop acquisition unit; a second voltage drop calculation unit that calculates a voltage drop in the low-voltage line after expansion as a second voltage drop based on the load to be added; a second terminal voltage calculation unit that calculates, as a second terminal voltage, a terminal voltage on the drop-in line side of the low-voltage line after the load is added, based on the first voltage drop and the second voltage drop; The present invention relates to a program that functions as a determination unit that determines whether or not the low-voltage line needs to be replaced based on terminal voltage.

According to the present invention, it is possible to provide a determination device and a program capable of optimizing implementation of low-voltage line relining work.

FIG. 2 is a schematic diagram showing power distribution equipment including low-voltage lines for which the necessity of relining work is determined by a determination device according to an embodiment of the present invention. FIG. 1 is a block diagram showing the configuration of a determination device according to an embodiment. It is a flowchart which shows the flow of operation of the judgment device of one embodiment.

Hereinafter, a determination device 1 and a program according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.
First, a power distribution facility 100 including a low-voltage line 103 for which the necessity of relining is determined by the determination device 1 according to the present embodiment will be described with reference to FIG. 1.

The power distribution equipment 100 is equipment for supplying low-voltage power from a power distribution line to each house or the like. The power distribution equipment 100 includes a pole transformer 102, a low voltage line 103, and a drop-in line 105.

Pole transformer 102 is placed on a utility pole. The primary side of the pole transformer 102 is connected to a high voltage distribution line. The pole transformer 102 steps down the power supplied from the high voltage distribution line 101. The pole transformer 102 steps down the voltage of approximately 6600V supplied from the high voltage distribution line 101 to approximately 100V, for example.

The low voltage line 103 is a wiring installed from the pole transformer 102 to the vicinity of each home or the like. The primary side of the low voltage line 103 is connected to the pole transformer 102. The secondary side (end side) of the low-voltage line 103 is installed on a utility pole (hereinafter also referred to as the end pole 104).

The drop-in line 105 is a wiring connected from the low-voltage line 103 to each home or the like. The primary side of the drop-in line 105 is connected to the secondary side of the low-voltage line 103 at the terminal post 104 . The secondary side of the lead-in line 105 is connected to each house or the like. The lead-in line 105 is installed, for example, for each house 106 (for example, for each building). Each house 106 is provided with a smart meter 116 that obtains voltage and current values, for example.

Next, a case where a new load is added will be explained.
Depending on the construction of a new house 106, a load may be added to the secondary side of the low-voltage line 103. In this case, the voltage drop in the low voltage line 103 increases depending on the size of the load. When the voltage drop increases, the voltage value on the secondary side of the low voltage line 103 decreases. On the other hand, if the voltage value at the end of the low-voltage line 103 is equal to or higher than the predetermined value, the voltage supplied to each house 106 will be equal to or higher than the predetermined value, so that it is possible to avoid relining the low-voltage line 103.

The determination device 1 and the program according to this embodiment calculate the voltage value at the end pole 104 of the low-voltage line 103 according to the added load. The determination device 1 and the program determine that reupholstery work is unnecessary when the calculated voltage value is equal to or higher than a predetermined value. Thereby, the determination device 1 and the program optimize the reupholstery work.

Next, the configuration of the determination device 1 of this embodiment will be explained with reference to FIG. 2.
The determination device 1 determines whether or not it is necessary to rewire the low-voltage line 103 disposed between the pole transformer 102 and the service line 105 in accordance with the addition of the load. The determination device 1 includes a first terminal voltage acquisition section 11, a first load current acquisition section 12, a first voltage drop calculation section 13, a second load current acquisition section 14, a second voltage drop calculation section 15, It includes a second terminal voltage calculation section 16, a determination section 17, and an output section 18.

The first terminal voltage acquisition unit 11 is realized, for example, by the operation of a CPU. The first terminal voltage acquisition unit 11 obtains the terminal voltage on the drop-in line 105 side of the low-voltage line 103 before expansion as the first terminal voltage. The first terminal voltage acquisition unit 11 acquires the voltage value of the terminal pole 104 of the low voltage line 103 by acquiring the value of a smart meter placed at the terminal pole 104 of the low voltage line 103, for example. The first terminal voltage acquisition unit 11 acquires the lowest voltage value among the terminal voltages as the first terminal voltage value, for example, in a predetermined period of time (for example, 30 minutes).

The first load current acquisition unit 12 is realized by, for example, operating a CPU. The first load current acquisition unit 12 acquires the load current flowing through the low voltage line 103 before expansion. The first load current acquisition unit 12 acquires the highest current value of the load currents as the first load current, for example, during a predetermined period of time (for example, 30 minutes).

The first voltage drop calculation unit 13 is realized by, for example, operating a CPU. The first voltage drop acquisition unit calculates the voltage value that drops in the low voltage line 103 before expansion as the first voltage drop. The first voltage drop acquisition unit calculates the first voltage drop based on, for example, the acquired first terminal voltage, the impedance of the low voltage line 103, and the acquired load current of the low voltage line 103.

The second load current acquisition unit 14 is realized, for example, by the operation of a CPU. The second load current acquisition unit 14 acquires a load current that is assumed to flow through the low voltage line 103 due to the overall load increased after the expansion. The second load current acquisition unit 14 acquires, for example, the highest current value among the assumed load currents as the second load current.

The second voltage drop calculation unit 15 is realized, for example, by the operation of a CPU. The second voltage drop calculation unit 15 calculates the voltage value that drops in the added low-voltage line 103 as a second voltage drop based on the added load. The second voltage drop calculation unit 15 calculates the second voltage drop based on, for example, the acquired first terminal voltage, the impedance of the low voltage line 103, and the load current that takes into account the expected load.

The second terminal voltage calculation unit 16 is realized by, for example, operating a CPU. The second terminal voltage calculation unit 16 calculates the terminal voltage on the drop-in line 105 side of the low-voltage line 103 after the load is added as the second terminal voltage, based on the first terminal voltage, the first voltage drop, and the second voltage drop. .
The second terminal voltage calculation unit 16, for example,
(First terminal voltage) - {(Second voltage drop) - (First voltage drop)}
By calculating , the second terminal voltage is calculated.
The second terminal voltage calculation unit 16 indicates the voltage value of the power drawn into each house 106 by the drop-in line 105.

The determination unit 17 is realized by, for example, operating a CPU. The determining unit 17 determines whether or not the low-voltage line 103 needs to be rewired based on the calculated second terminal voltage. The determining unit 17 determines whether or not the low-voltage line 103 needs to be replaced, for example, based on whether the second terminal voltage can maintain a predetermined standard voltage. The determination unit 17 determines whether or not re-covering is necessary, for example, based on whether the voltage value at the end pillar 104 of the low-voltage line 103 after expansion is equal to or higher than a predetermined value (for example, equal to or higher than 97 V). That is, the determination unit 17 determines that reupholstery work is necessary when the voltage value is less than a predetermined value. On the other hand, when the voltage value is equal to or higher than the predetermined value, the determination unit 17 determines that reupholstery work is unnecessary.

For example, as shown in FIG. 1, when the first voltage drop is 4.1V and the second voltage drop is 5.5V, the voltage drop for the load increase is 1.4V. If the voltage value of power supplied to each house 106 before expansion is 101V, the voltage value of power supplied to each house 106 after expansion is 99.6V. Since the voltage value after the expansion is 99.6V, which is higher than the predetermined voltage value (97V), the determination unit 17 determines that re-covering work is unnecessary.

The output unit 18 is realized by, for example, operating a CPU. The output unit 18 outputs the determination result to an output device such as a display or a printer, for example.

Next, the flow of the operation of the control device will be explained with reference to FIG.
First, the first terminal voltage acquisition unit 11 obtains a first terminal voltage (step S1). Next, the first load current acquisition unit 12 acquires the load current flowing through the low voltage line 103 before the load is added (step S2). Next, the first voltage drop calculation unit calculates a first voltage drop that is the voltage drop in the low voltage line 103 before the load is added (step S3).

Next, the second load current acquisition unit 14 acquires the load current that is assumed to flow through the low voltage line 103 after the load is added (step S4). Next, the second voltage drop calculation unit 15 calculates the voltage drop of the low voltage line 103 after the load is added as a second voltage drop (step S5). Next, the second terminal voltage calculation unit 16 calculates the voltage value of the low voltage line 103 at the terminal column 104 after the load is added as the second terminal voltage (step S6).

Next, the determining unit 17 determines whether the second terminal voltage is less than a predetermined value (step S7). If the second terminal voltage is less than the predetermined value (step S7: YES), the process proceeds to step S8. On the other hand, if the second terminal voltage is equal to or higher than the predetermined value (step S7: YES), the process proceeds to step S9.

In step S8, the determination unit 17 determines that reupholstery work is required. The output unit 18 outputs that reupholstery work is required. After that, the processing according to this flow ends.

In step S9, the determination unit 17 determines that reupholstery work is unnecessary. The output unit 18 outputs that reupholstery work is unnecessary. After that, the processing according to this flow ends.

Next, the program of this embodiment will be explained.
Each configuration included in the determination device 1 can be realized by hardware, software, or a combination thereof. Here, being realized by software means being realized by a computer reading and executing a program.

The program can be stored and delivered to a computer using various types of non-transitory computer readable media. Non-transitory computer-readable media includes various types of tangible storage media. Examples of non-transitory computer-readable media include magnetic recording media (e.g., flexible disks, magnetic tape, hard disk drives), magneto-optical recording media (e.g., magneto-optical disks), CD-ROMs (Read Only Memory), and CD-ROMs. R, CD-R/W, semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (random access memory)). The display program may also be provided to the computer via various types of transitory computer readable media. Examples of transitory computer-readable media include electrical signals, optical signals, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire L and an optical fiber, or a wireless communication path.

As described above, according to the determination device 1 and program of one embodiment, the following effects are achieved.
(1) A determination device 1 that determines whether or not a low-voltage line 103 placed between a pole transformer 102 and a drop-in line 105 needs to be re-wired in accordance with load addition, wherein the low-voltage line 103 before the addition a first terminal voltage acquisition section 11 that obtains the terminal voltage on the side of the drop-in line 105 as a first terminal voltage, and a first voltage drop calculation section 13 that calculates the voltage value dropped in the low-voltage line 103 before expansion as a first voltage drop. and a second voltage drop calculation unit 15 that calculates the voltage value that drops in the low-voltage line 103 after the expansion as a second voltage drop based on the load to be added; 2. A second terminal voltage calculation unit 16 calculates the terminal voltage on the drop-in line 105 side of the low-voltage line 103 after the load is added as a second terminal voltage based on the second voltage drop; A determination unit 17 that determines whether or not the wire 103 needs to be replaced is provided.
A program that causes a computer to function as a determination device 1 that determines whether or not a low-voltage line 103 placed between a pole transformer 102 and a service line 105 needs to be replaced in accordance with an increase in load. A first terminal voltage acquisition unit 11 that acquires the terminal voltage on the drop-in line 105 side of the low-voltage line 103 before expansion as a first terminal voltage; A voltage drop acquisition unit, a second voltage drop calculation unit 15 that calculates the voltage value that drops in the low-voltage line 103 after the expansion as a second voltage drop based on the added load, a first terminal voltage, a first voltage drop, and a second terminal voltage calculation unit 16 that calculates the terminal voltage on the drop-in line 105 side of the low-voltage line 103 after the load is added as the second terminal voltage based on the second voltage drop, and based on the calculated second terminal voltage, It functions as a determination unit 17 that determines whether or not the low-voltage line 103 needs to be replaced.
In contrast to the conventional method of determining whether or not re-paneling work is necessary based on the amount of voltage drop in the low-voltage line 103, the necessity of re-panling work is determined based on the voltage value of the electricity actually supplied to each house 106. You can decide whether it is necessary or not. Therefore, it is possible to determine whether or not re-paneling work is necessary while ensuring the voltage value supplied to each house 106. This makes it possible to optimize the execution of the re-covering work of the low-voltage line 103.

(2) The determining unit 17 determines whether or not the low-voltage line 103 needs to be replaced, based on whether the second terminal voltage can maintain a predetermined standard voltage. Thereby, it can be determined whether or not power can be stably supplied to each house 106.

(3) The second terminal voltage calculation unit 16 is
(First terminal voltage) - {(Second voltage drop) - (First voltage drop)}
Calculate. Thereby, it is possible to accurately calculate the second terminal voltage expected after the load is added.

Although a preferred embodiment of the judgment device and program of the present invention has been described above, the present invention is not limited to the above-described embodiment and can be modified as appropriate.

For example, in the embodiment described above, the determination device 1 may determine whether reupholstery is necessary based on the voltage drop during the season when power consumption is at its peak. For example, the first terminal voltage acquisition section 11 and the first load current acquisition section 12 calculate the lowest voltage value and the highest load current at a predetermined time in the season when power consumption is at its peak. It may also be acquired as the first load current value. Moreover, when the determination device 1 makes a determination in a season other than the peak season, the determination device 1 may make the determination again in the peak season. Further, the determination device 1 may determine whether or not re-covering work is necessary using the first terminal voltage and first load current value that have already been acquired during the peak season. This makes it possible to determine whether or not re-covering work is necessary depending on the situation where power consumption is at its maximum. Therefore, the accuracy of the determination result can be further improved.

Further, in the above embodiment, the first load power amount acquisition section and the second load power amount acquisition section acquire the load current, but the present invention is not limited thereto. The first load power amount acquisition section and the second power amount acquisition section may acquire the load amount. The first voltage drop calculation unit 13 and the second voltage drop calculation unit 15 may calculate the load current from the load amount.

1 Judgment device 11 First terminal voltage acquisition section 13 First voltage drop calculation section 15 Second voltage drop calculation section 16 Second terminal voltage calculation section 17 Judgment section 102 Pole transformer 103 Low voltage line 105 Drop line

Claims (5)

A determination device that determines whether or not a low-voltage line placed between a pole transformer and a drop-in line needs to be rewired in response to an increase in load,
a first terminal voltage acquisition unit that obtains a terminal voltage on the drop-in line side of the low-voltage line before expansion as a first terminal voltage;
a first voltage drop calculation unit that calculates a voltage value that drops in the low voltage line before expansion as a first voltage drop;
a second voltage drop calculation unit that calculates, as a second voltage drop, a voltage value that drops in the low-voltage line after the addition, based on the load that is added;
a second terminal voltage calculation unit that calculates, as a second terminal voltage, a terminal voltage on the service line side of the low-voltage line after adding a load, based on the first terminal voltage, the first voltage drop, and the second voltage drop; and,
a determination unit that determines whether or not the low-voltage line needs to be rewired based on the calculated second terminal voltage;
A judgment device equipped with. The determination device according to claim 1, wherein the determination unit determines whether or not the low-voltage line needs to be replaced based on whether or not the second terminal voltage can maintain a predetermined standard voltage. The second terminal voltage calculation unit includes:
(The first terminal voltage)-{(the second voltage drop)-(the first voltage drop)}
The determination device according to claim 1 or 2, wherein the second terminal voltage is calculated by calculating . The determination device according to any one of claims 1 to 3, wherein the second voltage drop calculation unit determines whether or not the low-voltage line needs to be replaced based on a voltage drop during a season when power consumption is at its peak. A program that causes a computer to function as a determination device that determines whether or not a low-voltage line placed between a pole transformer and a service line needs to be rewired in response to an increase in load, the program comprising:
The computer,
a first terminal voltage acquisition unit that obtains a terminal voltage on the drop-in line side of the low-voltage line before expansion as a first terminal voltage;
a first voltage drop acquisition unit that acquires a voltage value that drops in the low-voltage line before expansion as a first voltage drop;
a second voltage drop calculation unit that calculates, as a second voltage drop, a voltage value that drops in the low-voltage line after the addition, based on the load that is added;
a second terminal voltage calculation unit that calculates, as a second terminal voltage, a terminal voltage on the service line side of the low-voltage line after adding a load, based on the first terminal voltage, the first voltage drop, and the second voltage drop; ,
a determination unit that determines whether or not the low-voltage line needs to be rewired based on the calculated second terminal voltage;
A program that functions as

Images