KR102596463B1 - HVDC output limit determination apparatus and method - Google Patents

Abstract

The present invention relates to an HVDC monitoring device and method for determining an output limit value of an HVDC and monitoring the HVDC output so that it does not exceed the output limit value.
According to an embodiment of the present invention, the HVDC output limit determination device includes an input unit that receives power system data and an output value of HVDC (High Voltage Direct Current), and calculates the output limit value of the HVDC through the power system data input from the input unit. and a calculation unit for comparing the output limit value of the HVDC with the output value of the HVDC, and as a result of comparing the output limit value of the HVDC with the output value of the HVDC in the calculation unit, the output value of the HVDC is equal to the output limit value of the HVDC. If it exceeds it, it includes an output unit that provides comparison results to HMI (Human Machine Interface).

Description

HVDC output limit determination apparatus and method {HVDC output limit determination apparatus and method}

The present invention relates to an apparatus and method for determining an HVDC output limit, and more specifically, to an apparatus and method for determining an HVDC output limit that determines the output limit of an HVDC and monitors the output of the HVDC so that it does not exceed the output limit.

The power system represents a system that goes from generation to consumption of electricity by connecting power plants, substations, and loads with transmission lines in response to demand for electricity.

Recently, as one of the power system systems, high voltage direct current (HVDC) transmission facilities have been developed that convert AC power produced at power plants into direct current, transmit it, and then reconvert it to alternating current at the receiving point to supply power. Unlike AC system lines, HVDC facilities can control power flow, but the power flow control of HVDC facilities can affect the AC system. In particular, current-type HVDC equipment varies in reactive power consumption depending on the output size of the HVDC equipment, and accordingly requires a filter that supplies reactive power. At this time, there is a problem in that the rapidly changing output of HVDC equipment has a significant impact on the voltage fluctuations of the AC system.

The present invention is intended to solve the problems described above, and its purpose is to provide an HVDC output limit determination device and method that determines the output limit value of the HVDC and monitors the HVDC output so that it does not exceed the output limit value.

In addition to the technical problems of the present invention mentioned above, other features and advantages of the present invention are described below, or can be clearly understood by those skilled in the art from such description and description.

An HVDC output limit determination device according to an embodiment of the present invention to achieve the purpose described above includes an input unit that receives power system data and the output value of HVDC (High Voltage Direct Current), and an input unit that receives HVDC (High Voltage Direct Current) output values. A calculation unit calculates the output limit value and compares the output limit value of HVDC with the output value of HVDC, and as a result of comparing the output limit value of HVDC with the output value of HVDC in the calculation unit, the output value of HVDC exceeds the output limit value of HVDC. In this case, it may include an output unit that provides comparison results through an HMI (Human Machine Interface).

Here, the input unit can receive power system data required for system analysis from SCADA or EMS, which provides power system data in PTI format in real time.

Additionally, the input unit can periodically receive the HVDC output value from the HVDC whose output limit is to be determined.

In addition, the calculation unit calculates the SCC (Short Circuit Capacity) of the power receiving end of the HVDC using Equation 1 below,

[Equation 1]

SCC is the short-circuit capacity of the receiving end of the HVDC, V is the rated voltage of the power system, and Is may be the short-circuit current or the fault current that flows when the receiving end of the HVDC fails.

In addition, the calculation unit uses the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below,

[Equation 2]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of the HVDC, and A can be a constant of 3 or more.

In addition, the calculation unit uses the calculated SCC to calculate the output limit value for the effective short-circuit ratio using Equation 3 below,

[Equation 3]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of the HVDC, Q is the reactive power consumed by the HVDC, and B can be a constant of 2.5 or more.

In addition, the calculation unit uses the calculated SCC to calculate the output limit considering the HVDC installed nearby using Equation 4 below,

[Equation 4]

is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC installed nearby, is the reactive power consumed by the HVDC installed nearby, C is a constant of 2.5 or more, is the output value of the HVDC installed nearby, may be a value indicating the degree of influence of voltage fluctuations between HVDCs installed nearby.

Also, the calculation part is Calculate with Equation 5 below,

[Equation 5]

is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs between regions, may be the voltage change value of HVDCs within a certain area.

Additionally, the calculated output limit value can be compared with the HVDC output to determine whether the HVDC output exceeds the calculated output limit value.

Additionally, it is possible to determine whether the HVDC output exceeds the calculated output limit value by comparing the smallest value among the calculated output limit values with the HVDC output.

On the other hand, the method for determining the HVDC output limit according to an embodiment of the present invention to achieve the purpose described above includes the steps of receiving power system data and the output value of the HVDC from the input unit, and the output limit of the HVDC through the power system data input from the calculation unit. A step of calculating a value, a step of comparing the output limit value of the HVDC with the output value of the HVDC in the calculation unit, and if the output value of the HVDC exceeds the output limit value of the HVDC in the output unit, the comparison result is reported to the HMI (Human Machine Interface). It may include providing steps.

Here, in the input stage, the power system data required for system analysis can be received from SCADA or EMS, which provides power system data in PTI format in real time at the input unit.

Additionally, in the input receiving step, the HVDC output value can be periodically input from the HVDC whose output limit is to be determined at the input unit.

In addition, in the calculation step, the calculation unit calculates the SCC (Short Circuit Capacity) of the power receiving end of the HVDC using Equation 1 below,

[Equation 1]

SCC is the short-circuit capacity of the receiving end of the HVDC, V is the rated voltage of the power system, and Is may be the short-circuit current or the fault current that flows when the receiving end of the HVDC fails.

In addition, in the calculation step, the calculation unit uses the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below,

[Equation 2]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of the HVDC, and A can be a constant of 3 or more.

In addition, in the calculation step, the calculation unit uses the calculated SCC to calculate the output limit value for the effective short-circuit ratio using Equation 3 below,

[Equation 3]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of the HVDC, Q is the reactive power consumed by the HVDC, and B can be a constant of 2.5 or more.

In addition, in the calculation step, the calculation unit uses the calculated SCC to calculate the output limit considering the HVDC installed nearby using Equation 4 below,

[Equation 4]

is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC installed nearby, is the reactive power consumed by the HVDC installed nearby, C is a constant of 2.5 or more, is the output value of the HVDC installed nearby, may be a value indicating the degree of influence of voltage fluctuations between HVDCs installed nearby.

Additionally, in the calculation step, Calculate with Equation 5 below,

[Equation 5]

is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs between regions, may be the voltage change value of HVDCs within a certain area.

Additionally, in the comparison step, the calculated output limit value can be compared with the HVDC output to determine whether the HVDC output exceeds the calculated output limit value.

Additionally, in the comparison step, the smallest value among the calculated output limit values can be compared with the output of the HVDC to determine whether the output of the HVDC exceeds the calculated output limit value.

The apparatus and method for determining the HVDC output limit according to an embodiment of the present invention can monitor the output of the HVDC so that it does not exceed the output limit.

In addition, it is possible to determine in advance whether HVDC output may affect the power system in the event of a predicted failure, so HVDC can be optimally operated so as not to violate the reliability of the power system.

In addition, other features and advantages of the present invention may be newly understood through embodiments of the present invention.

1 is a diagram showing data input to an HVDC output limit determination device according to an embodiment of the present invention.
Figure 2 is a diagram showing the configuration of an HVDC output limit determination device according to an embodiment of the present invention.
Figure 3 is a diagram showing a method for determining an HVDC output limit according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts that are not relevant to the description are omitted, and identical or similar components are assigned the same reference numerals throughout the specification.

Throughout the specification, when a part is said to be "connected" to another part, this includes not only the case where it is "directly connected," but also the case where it is "electrically connected" with another element in between. . Additionally, when a part "includes" a certain component, this means that it may further include other components rather than excluding other components, unless specifically stated to the contrary.

The terminology used herein is only intended to refer to specific embodiments and is not intended to limit the invention. As used herein, singular forms include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" refers to specifying a particular characteristic, area, integer, step, operation, element and/or ingredient, and the presence or presence of another characteristic, area, integer, step, operation, element and/or ingredient. This does not exclude addition.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

1 is a diagram showing data input to an HVDC output limit determination device according to an embodiment of the present invention.

Referring to FIG. 1, the HVDC output limit determination device 100 according to an embodiment of the present invention may be used to determine the HVDC (High Voltage Direct Current) output limit by reflecting the real-time situation of the power system. HVDC (300) complements the shortcomings of the AC system, such as long-distance transmission and fixed current increase problems, and is capable of controlling power flow. However, if the output of the HVDC (300) changes rapidly during power flow control of the HVDC (300), the AC system may be affected. Accordingly, the present invention is an HVDC output limit determination device (100) that determines an output limit value that does not affect the AC system even if the output of the HVDC (300) changes rapidly and monitors whether the output of the HVDC (300) exceeds the output limit value. ) can be provided. Specifically, the HVDC output limit determination device 100 may receive power system data from a power system (Power System) 200 and receive HVDC data from the HVDC (300). The HVDC output limit determination device 100 can calculate the output limit value using power system data and monitor whether the HVDC output (HVDC data) exceeds the calculated output limit value.

Figure 2 is a diagram showing the configuration of an HVDC output limit determination device according to an embodiment of the present invention.

Referring to FIG. 2, the HVDC output limit determination device 100 according to an embodiment of the present invention may include an input unit 110, a calculation unit 120, and an output unit 130.

The input unit 110 can receive data from the power system (Power System) 200 and the HVDC (300). Specifically, the input unit 110 can receive power system data from SCADA or EMS, which provides power system data in PTI format in real time. Here, power system data is data necessary for system analysis and may include rated voltage, short-circuit current, etc. Additionally, the input unit 110 may periodically receive data from the HVDC 300 to determine the output limit, and the data received from the HVDC 300 may be an output value of the HVDC 300.

The calculation unit 120 may calculate the output limit value of the HVDC 300 through data received from the input unit 110. First, the calculation unit 120 can calculate the short circuit capacity (SCC) of the power receiving end side of the HVDC 300 using Equation 1 below.

[Equation 1]

Here, SCC is the short-circuit capacity of the receiving end of the HVDC (300), V is the rated voltage of the power system, and Is is the short-circuit current or fault current that flows when the receiving end of the HVDC (300) fails.

Afterwards, the calculation unit 120 can use the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below.

[Equation 2]

here, is the output limit value, SCC is the short-circuit capacity of the receiving end side of the HVDC (300), and A is a constant of 3 or more.

Additionally, the calculation unit 120 can use the calculated SCC to calculate the output limit value for the effective short-circuit ratio using Equation 3 below.

[Equation 3]

here, is the output limit value, SCC is the short-circuit capacity of the receiving end side of the HVDC (300), Q is the reactive power consumed by the HVDC (300), and B is a constant of 2.5 or more.

Additionally, the calculation unit 120 can use the calculated SCC to calculate the output limit considering the HVDC 300 installed nearby using Equation 4 below.

[Equation 4]

here, is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC (300) installed nearby, is the reactive power consumed by the HVDC (300) installed nearby, and C is a constant of 2.5 or more. also, is the output value of the HVDC (300) installed nearby, is a value indicating the degree of influence of voltage fluctuations between HVDCs (300) installed nearby. here, Can be calculated using Equation 5 below.

[Equation 5]

here, is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs 300 between regions, is the voltage change value of HVDCs 300 within a certain area.

Additionally, the calculation unit 120 may compare the output limit value calculated above with the output of the HVDC 300 to determine whether the output of the HVDC 300 exceeds the calculated output limit value. Here, the calculation unit 120 selects one of the output limit value for the short-circuit ratio, the output limit value for the effective short-circuit ratio, and the output limit value considering the HVDC (300) installed nearby and compares it with the output of the HVDC (300). there is.

In addition, the calculation unit 120 compares the output of the HVDC (300) with the smallest value among the output limit value for the short-circuit ratio, the output limit value for the effective short-circuit ratio, and the output limit value considering the HVDC (300) installed nearby. It can be determined whether the output of the HVDC (300) exceeds the calculated output limit value.

The output unit 130 may provide a result to a human machine interface (HMI) when the output of the HVDC 300 exceeds the calculated output limit value. When the output of the HVDC 300 exceeds the output limit calculated by the calculation unit 120, the output unit 130 generates a result that the output of the HVDC 300 exceeds the output limit calculated by the calculation unit 120. You can print it out so the reviewer can check it. The reviewer can monitor the output of the HVDC (300) through the results output to the output unit 130, and further prevents it from affecting the voltage fluctuation of the AC system when the output of the HVDC (300) changes rapidly. You can take action early to do this.

Figure 3 is a diagram showing a method for determining an HVDC output limit according to an embodiment of the present invention.

Referring to FIG. 3, the input unit 110 can receive data from the power system and the HVDC 300 (S10). Specifically, the input unit 110 can receive power system data from SCADA or EMS, which provides power system data in PTI format in real time. Here, power system data is data necessary for system analysis and may include rated voltage, short-circuit current, etc. Additionally, the input unit 110 may periodically receive the output value of the HVDC 300 from the HVDC 300 for which the output limit is to be determined.

The calculation unit 120 may calculate the output limit value of the HVDC 300 through data received from the input unit 110 (S20). First, the calculation unit 120 can calculate the short circuit capacity (SCC) of the power receiving end side of the HVDC 300 using Equation 1 below.

[Equation 1]

Here, SCC is the short-circuit capacity of the receiving end of the HVDC (300), V is the rated voltage of the power system, and Is is the short-circuit current or fault current that flows when the receiving end of the HVDC (300) fails.

Afterwards, the calculation unit 120 can use the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below.

[Equation 2]

here, is the output limit value, SCC is the short-circuit capacity of the receiving end side of the HVDC (300), and A is a constant of 3 or more.

Additionally, the calculation unit 120 can use the calculated SCC to calculate the output limit value for the effective short-circuit ratio using Equation 3 below.

[Equation 3]

here, is the output limit value, SCC is the short-circuit capacity of the receiving end side of the HVDC (300), Q is the reactive power consumed by the HVDC (300), and B is a constant of 2.5 or more.

Additionally, the calculation unit 120 can use the calculated SCC to calculate the output limit considering the HVDC 300 installed nearby using Equation 4 below.

[Equation 4]

here, is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC (300) installed nearby, is the reactive power consumed by the HVDC (300) installed nearby, and C is a constant of 2.5 or more. also, is the output value of the HVDC (300) installed nearby, is a value indicating the degree of influence of voltage fluctuations between HVDCs (300) installed nearby. here, Can be calculated using Equation 5 below.

[Equation 5]

here, is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs 300 between regions, is the voltage change value of HVDCs 300 within a certain area.

Next, the calculation unit 120 may compare the output limit value calculated above with the output of the HVDC 300 to determine whether the output of the HVDC 300 exceeds the calculated output limit value (S30). Here, the calculation unit 120 selects one of the output limit value for the short-circuit ratio, the output limit value for the effective short-circuit ratio, and the output limit value considering the HVDC (300) installed nearby and compares it with the output of the HVDC (300). , the output of the HVDC (300) can be compared with the smallest value among the output limit value for the short-circuit ratio, the output limit value for the effective short-circuit ratio, and the output limit value considering the HVDC (300) installed nearby.

As a result of comparing the output of the HVDC 300 and the output limit value, the output unit 130 may provide the result to the Human Machine Interface (HMI) if the output of the HVDC 300 exceeds the output limit value (S40) . If the output of the HVDC 300 exceeds the output limit, the output unit 130 may output a result indicating the exceedance so that the reviewer can check this. The reviewer can monitor the output of the HVDC (300) through the results output to the output unit (130).

As described above, the present invention can provide an HVDC monitoring device and method for monitoring the HVDC output to ensure that it does not exceed the output limit.

Those skilled in the art to which the present invention pertains should understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features, and that the embodiments described above are illustrative in all respects and not restrictive. Just do it. The scope of the present invention is indicated by the claims described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. .

100: HVDC output limit determination device
200: Power system
300: HVDC
110: input unit
120: calculation unit
130: output unit
140: HMI

Claims (20)

An input unit that receives power system data and HVDC (High Voltage Direct Current) output values;
a calculation unit that calculates an output limit value of the HVDC using power system data received from the input unit and compares the output limit value of the HVDC with the output value of the HVDC; and
As a result of comparing the output limit value of the HVDC with the output value of the HVDC in the calculation unit, if the output value of the HVDC exceeds the output limit value of the HVDC, an output unit that provides a comparison result to an HMI (Human Machine Interface); Including,
The calculation unit calculates the SCC (Short Circuit Capacity) of the power receiving end of the HVDC using Equation 1 below,
[Equation 1]

SCC is the short-circuit capacity of the receiving end of the HVDC, V is the rated voltage of the power system, Is is the short-circuit current or fault current that flows when a fault occurs on the receiving end of the HVDC,
The calculation unit uses the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below,
[Equation 2]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of HVDC, A is a constant of 3 or more,
The calculation unit uses the calculated SCC to calculate the output limit considering the HVDC installed nearby using Equation 4 below,
[Equation 4]

is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC installed nearby, is the reactive power consumed by the HVDC installed nearby, C is a constant of 2.5 or more, is the output value of the HVDC installed nearby, is an HVDC output limit determination device that is a value that indicates the degree to which voltage fluctuations between HVDCs installed nearby are affected.
According to paragraph 1,
The input unit is an HVDC output limit determination device that receives power system data required for system analysis from SCADA or EMS, which provides power system data in PTI format in real time. According to paragraph 1,
The input unit is an HVDC output limit determination device that periodically receives an HVDC output value from the HVDC whose output limit is to be determined. delete delete delete delete According to paragraph 1,
The calculation unit is Calculate with Equation 5 below,
[Equation 5]

is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs between regions, is a device that determines the HVDC output limit, which is the voltage change value of HVDCs within a certain area. According to paragraph 1,
An HVDC output limit determination device that compares the calculated output limit value with the output of the HVDC to determine whether the output of the HVDC exceeds the calculated output limit value. According to paragraph 1,
An HVDC output limit determination device that compares the smallest value among the calculated output limit values with the output of the HVDC to determine whether the output of the HVDC exceeds the calculated output limit value. Receiving power system data and HVDC output values from an input unit;
Calculating an output limit value of the HVDC using the input power system data in a calculation unit;
Comparing the output limit value of the HVDC with the output value of the HVDC in the calculation unit; and
Including providing a comparison result to an HMI (Human Machine Interface) when the output value of the HVDC exceeds the output limit value of the HVDC at the output unit,
In the above calculation step,
The calculation unit calculates the SCC (Short Circuit Capacity) of the power receiving end of the HVDC using Equation 1 below,
[Equation 1]

SCC is the short-circuit capacity of the receiving end of the HVDC, V is the rated voltage of the power system, Is is the short-circuit current or fault current that flows when a fault occurs on the receiving end of the HVDC,
The calculation unit uses the calculated SCC to calculate the output limit value for the short circuit ratio using Equation 2 below,
[Equation 2]

is the output limit value, SCC is the short-circuit capacity of the power receiving end of HVDC, A is a constant of 3 or more,
In the above calculation step,
The calculation unit uses the calculated SCC to calculate the output limit considering the HVDC installed nearby using Equation 4 below,
[Equation 4]

is the output limit value, is the short-circuit capacity of the power receiving end of the HVDC installed nearby, is the reactive power consumed by the HVDC installed nearby, C is a constant of 2.5 or more, is the output value of the HVDC installed nearby, is a method of determining the HVDC output limit, which is a value that indicates the degree to which voltage fluctuations between HVDCs installed nearby are affected.
The method of claim 11, wherein in the step of receiving input,
A method for determining HVDC output limits that receives power system data required for system analysis from SCADA or EMS, which provides power system data in PTI format in real time from the input unit. The method of claim 11, wherein in the step of receiving input,
A method for determining an HVDC output limit in which the HVDC output value is periodically input from the HVDC whose output limit is to be determined at the input unit. delete delete delete delete The method of claim 11, wherein in the calculating step,
The calculation unit is Calculate with Equation 5 below,
[Equation 5]

is a value that represents the degree of influence of voltage fluctuations between HVDCs installed nearby, is the voltage change value of HVDCs between regions, is a method of determining the HVDC output limit, which is the voltage change value of HVDCs within a certain area. The method of claim 11, wherein in the comparing step,
A method for determining an HVDC output limit by comparing the calculated output limit with the output of the HVDC to determine whether the output of the HVDC exceeds the calculated output limit. The method of claim 11, wherein in the comparing step,
A method for determining the HVDC output limit by comparing the smallest value among the calculated output limit values with the output of the HVDC to determine whether the output of the HVDC exceeds the calculated output limit value.

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