KR200305090Y1 - Electric power error counting equipment - Google Patents

Abstract

The present invention is intended for use in calculating electricity rates by accurately measuring the metering error of the amount of power received or transmitted by a customer who is grounding a neutral point in the form of receiving power or transmitting surplus power produced by the customer to an electric company. It relates to a three-phase power metering error measurement device.

In general, the electricity supplier and the customer calculate the electricity charge based on the amount of electricity transmitted and received by the two-element metering device. Since the two-element metering device has an excessive amount of power generation error, recently, a three-element metering device has been installed to improve the accuracy of the amount of power transmitted and received.

However, the new faucet facility adopts the three-element metering device as described above. A power outage is accompanied by loss of tangible and intangibles, such as shutdown of production facilities.

Therefore, the present invention provides a simple device without a power failure for a separate device consisting of a low voltage current transformer for measuring the image current of the neutral point ground line of the power equipment installed by the two-element metering device and two three-phase power meters for measuring the system error of the power transmission and reception. The present invention relates to an apparatus for accurately metering the amount of power caused by an actual system error except for an instrument error among the installed and transmitted power.

Description

Three-phase power metering error measuring device {Electric power error counting equipment}

The present invention relates to a three-phase power metering error checking device, and more specifically, when a customer who grounds the 154kv side of the grid-connected transformer neutral receives power from the electricity supplier or supplies surplus power of the customer to the electricity provider. The present invention relates to a measurement error checking device for accurately measuring the system error of the amount of power to be measured.

In the case of the customer who has the power receiving equipment grounded at the neutral point of the 154kv side of the grid linkage transformer, when the electric power is supplied from the electricity supplier or the surplus power is supplied reversely, A metering device is installed at a certain point of the faucet, and the amount of electricity is measured and reflected in the electricity bill. Most of the metering devices adopt a two-element metering device consisting of two current transformers and three instrument transformers. .

However, when the power amount is measured by the two-element metering device as described above, the power factor cosθ = 1 in the apparatus of FIG. 1 is taken as an example.

W = W ₁ + W ₂ = V _ab I _a + V _cb I _c

= (V _a -V _b ) I _a + (V _c -V _b ) I _c

= V _a I _{a +} V _c I _c -V _b (I _a + I _c )

= V _a I _{a +} V _c I _c + V _b (I _b + I _n )

= (V _an + V _n ) I _a + (V _cn + V _n ) I _c + (V _bn + V _n ) (I _b + I _n )

= (V _an I _a + V _bn I _b + V _cn I _c ) + V _n (I _b + I _n + I _c ) + V _bn I _n + V _n I _n I _a + I _b + I _n =- Since I _n

= (V _an I _a + V _bn I _b + V _cn I _c ) + V _bn I _n , so power is generated as V _bn I _{n, which} is the neutral ground load, so that the actual amount of V _an I _a + V _bn I _b + V _c -V _cn I _n and I _n suyongga when the power reception over by _{V bn I n + V n I} n metering and when suyongga a transmission power surplus _{V bn I n + V n I} n as compared It is under-measured and is a very disadvantageous weighing method in which the amount of power is under-measured.

In order to compensate for the unreasonable power billing system of the customer who grounded the 154kv neutral point of the grid linking transformer, the inventors insisted that the three-phase metering device be installed with a one-to-one counterpart between the current transformer and the instrument transformer. We have previously filed a method for measuring the amount of electricity.The technical point is to install a current transformer and an instrument transformer at a certain point in a one-to-one correspondence between each phase, and transmit surplus power from the electric service provider to the electric service provider or vice versa. It is to measure the amount of power when

The amount of power measured by the three-element metering device as described above is

For example, cosθ = 1 (power factor 100%)

W = W ₁ + W ₂ + W ₃

= V _a I _a cosθ + V _b I _b cosθ + V _c I _c cosθ

= (V _an + V _n ) I _a + (V _bn + V _n ) I _b + (V _cn + V _n ) I _c

= V _an I _a + V _bn I _b + V _cn I _c + V _n (I _a + I _b + I _c ) and I _a + I _b + I _c = -I _n

= V _an I _a + V _bn I _b + V _cn I _c -V _n I _n to match the actual amount of power before and after transmission.

However, if you want to convert the equipment to a three-element metering device, you must not only install an expensive large-capacity current transformer, but also follow up the plant's temporary shutdown due to the power failure. The system error and instrument error caused by the operation of the facility are mixed, and the amount of power corresponding to the system error except for the instrument error allowed by the law remains a problem in the electricity bill settlement.

The present invention is designed to solve the above problems, and by attaching a simple measurement error measuring device without additional equipment replacement in the faucet facility that grounded the 154kv side neutral point of the system linkage transformer that maintains the existing two-element metering method. This eliminates the need for expensive current transformer installation and power outage due to the installation of the current transformer as in the three-element metering device, and only the errors in the system except for the instrument error, which is difficult to distinguish from the power error measured in the three-element metering device. It is an object of the present invention to provide a device of the present invention to a consumer who needs accurate measurement.

1 is a block diagram of a two-element metering device

2 is a block diagram of a three-element metering device

3 is a block diagram of a measurement error measuring device according to the present invention

4 is an embodiment of a measurement error measuring device according to the present invention

* Description of the main parts of the drawings *

10. Current transformer for low pressure 20. Three-phase power meter for measuring power errors

30: 3-phase electricity meter for transmission error measurement

The structure of the present invention for achieving the above object is a two-element metering method consisting of two current transformers and three instrument transformers while maintaining the power equipment grounded to the 154kv side neutral point of the grid-connected transformer to transmit and receive power In the well-known power equipment owned by the customer who is weighing, it is configured to add a separate low-voltage current transformer and two three-phase power meters to measure the amount of power before and after transmission. It is to provide a three-phase power metering error measurement device that can be.

Hereinafter, a three-phase power metering error measuring apparatus according to the present invention having the characteristics as described above will be described in detail with reference to the accompanying drawings.

3 is a configuration diagram of the present invention consisting of a low-pressure current transformer 10, a three-phase electricity meter 20 for measuring power transmission errors, and a three-phase electricity meter 30 for measuring transmission power errors.

As shown, the primary current side of the low-voltage current transformer 10 is 154kv of the grid-linked transformer in a known consumer faucet facility that measures the amount of power transmission and reception by a two-element metering device composed of two current transformers and three instrument transformers. The secondary current side of the low-voltage current transformer 10 is configured to be connected to a specific terminal of the power supply error metering 20 and the transmission error metering three-phase power meter 30 among the three-phase power meter.

The mutual connection of two three-phase electricity meter for measuring transmission and reception errors is connected to one end of the secondary current side of the low voltage current transformer and the 1S terminal of the three-phase electricity meter for power reception error measurement. The 1L terminal of the error metering 3-phase meter 20 is connected to the 1L terminal of the 3-phase meter for 30 transmission power metering, and the other end of the low-voltage current transformer is connected to the 1S terminal of the 3-phase meter for metering transmission error 30. 4 or the 2S terminal of the three-phase power meter 20 for power supply error metering and one end of the secondary current side of the low voltage current transformer, and the other end of the secondary current side of the low voltage current transformer is used for metering transmission error. The 2S terminal of the three-phase electricity meter 30 is connected, and the mutual connection of the three-phase electricity meter for power reception and transmission error metering is connected between the 2L terminals.

Wiring with the above configuration is possible to use single-phase electricity meter, but it is for use of three-phase electricity meter that can be divided into hourly division meter in the market because it is not classified according to the electricity tariff structure. ,

In the measurement of the amount of error power transmitted and received between the electric service provider and the customer based on the device of the present invention,

When you first receive electricity from a utility company,

The total amount of power received is metered based on the two-element metering device. The system error is that the current of the neutral ground line of the power receiving equipment is connected to the existing instrument transformer whose system error is checked through one end of the low-voltage transformer. To 1L terminal of the three-phase power meter for transmission error measurement of the present invention is inputted to the 1S terminal of the three-phase power meter for power transmission error metering of the invention and connected to the existing instrument transformer through the 1L terminal. Although it is input, the three-phase electricity meter for transmission error metering is not metered in the electricity meter for transmission because it is connected to the same terminal as shown in FIG.

On the contrary, when the customer transmits electricity to the electric service provider, since the current direction of the image current of the neutral ground wire is changed in FIG. 3, the current direction of the low pressure current transformer 10 is reversed, so that the three-phase power meter for measuring transmission power from the low pressure current transformer 10 ( Input to the 1S terminal of 30) and then input via the 1L terminal to the 1L terminal of the three-phase electricity meter for power metering error measurement, but the power meter for metering power metering error (20) by the wiring structure so that the wiring of the positive meter is the same terminal 4, the embodiment of FIG. 4 also flows into the 2S terminal of the transmission error metering power meter 30 from the low voltage transformer 10 and then inputs to the 2L terminal of the power metering metering power meter via the 2L terminal. However, due to the same terminal wiring structure of the positive watt-hour meter, the meter cannot be metered in the power meter for measuring power errors and has a general knowledge in the technical field to which the present invention belongs. Surface would be susceptible to various embodiments of the connection structure.

Comparing the value calculated by the measurement error measurement device and the voltage current measurement value according to the present invention configured as described above is the amount of power measured in the present invention is the deviation of the amount of power measured in the known two-element metering device and The amount of system error by the device metering device, and the deviation (16kw) between the value calculated by measuring the voltage current is generated in this case, the continuous accumulation value and the calculated value is calculated by the average of the instantaneous values. Deviation due to

<Measurement result>

Measured value of this invention Measured value by instrument Deviation (kw) Measurement average Calculated Value 1356kw Vb = 89930∠1171.7In = 1535∠178.2Vn = 4260∠166.2Qb = 6.49Qn = 12/02 P = V _b I _n cosθ _b (89930 × 15.35) cos6.49 = 1372kw 16

※ Calculated by averaging the measured value every 24 hours every 2 hours

The comparison result of the measured values is calculated by averaging the measured value of the voltage and current value at 2 hour intervals for 24 hours for the convenience of comparison. Because there is a difference in the comparison by dividing by, there may be a slight difference in reality, but in case of continuous metering, the amount of power accurately measures only the system error.

In the case of a customer who measures power before transmission based on the two-element metering device according to the present invention, a three-element metering method is required to derive a weighing error, but for this, an additional expensive high-power current transformer needs to be added. Loss of plant shutdown due to power failure caused by installing the current transformer is inevitable.

However, in the present invention, the above problem does not occur at all, and it is applicable to the case where the system error that is difficult to extract separately from the three-element metering device can be applied. Can be calculated accurately.

Claims (3)

Measurement error of power transmission / reception in the power receiving equipment grounded at the 154kv side neutral point of the grid-connected transformer measuring the transmission and reception power by a two-element metering device consisting of two current transformers (CT) and three instrument transformers (PT) In order to derive a low-voltage current transformer 10, power metering error, power transmission metering three-phase power meter for measuring the power amount of the metering error, and transmission error metering three-phase power meter (30) Three-phase power metering error measuring device, characterized in that for measuring the system error of the amount of power before transmission According to claim 1, the primary current side of the low-voltage current transformer 10 is electrically connected to the ground line of the power receiving equipment grounded 154kv side neutral point of the transformer for grid linkage, the secondary current side is a three-phase power meter (20) Three-phase power metering error measurement device, characterized in that the electrical connection of the specific terminal of the terminal and the specific terminal of the terminal of the three-phase power meter for transmission error metering (30) The method of claim 1, wherein the three-phase power meter 20 for power reception power metering and the three-phase power meter 30 for power transmission power metering are electrically connected to a specific terminal such as mutually, and the power supply error metering 20 and Three-phase power metering measurement device, characterized in that the specific terminal of the three-phase power meter for the transmission error metering (30) is electrically connected to the instrument transformer of a known two-element metering device