KR102695714B1 - Self-recovery relay system with remote communication function applied to solar power facilities - Google Patents

Abstract

The present invention relates to an automatic recovery relay system having a remote communication function applied to a solar power facility, comprising: a relay panel having a main body of a predetermined size; a protection relay configured to sample voltage or current of a transmission and distribution line or power system of a solar power generation facility, measure the operation result data obtained by performing a preset relay algorithm operation using the sampled data as source data, and cut off the grid power when an abnormality in the grid power is determined through the measurement; A first circuit breaker section comprising: an instrument transformer and an instrument transformer local control panel; wherein the voltage transmitted from each phase of a power line bus is transformed into an instrument voltage by the instrument transformer; and then, under the control of the instrument transformer local control panel, a voltage measurement value (Voltage Measurement) is provided to the protection relay through an instrument transformer test terminal (PTT (PT Test Terminal)) among test terminals set for each phase of the power line bus; and an instrument current transformer and an instrument current transformer local control panel; wherein the current transmitted from each phase of the power line bus is transformed into an instrument voltage by the instrument current transformer; and then, under the control of the instrument current transformer local control panel, a current measurement value (Current Measurement) is provided to the protection relay through an instrument current transformer test terminal (CTT (CT Test Terminal)) among test terminals set for each phase of the power line bus; and when it is determined that an abnormality has occurred in the power line power, the first circuit breaker section cuts off the power supplied to the outside; It is configured to include a second circuit breaker unit for cutting off grid power supplied to an external inverter device when an abnormality in the power of the above power system is determined; and a remote communication module for transmitting a cutting signal depending on whether grid power supplied externally is cut off based on abnormal signals of voltage measurement values and current measurement values detected by the protection relay, and a recovery signal depending on a recovery operation in case of cutting off, to the outside through a wireless communication network or receiving a control command signal from the outside.

Description

{Self-recovery relay system with remote communication function applied to solar power facilities}

The present invention relates to an automatic recovery relay system having a remote communication function applicable to solar power facilities, and more specifically, to an automatic recovery relay system having a remote communication function applicable to solar power facilities that enables remote control between power distribution and panels in solar power generation facilities by applying a remote communication function.

When a fault occurs in a transmission and distribution line, power system, or specific power facility, overvoltage, undervoltage, overcurrent, or frequency fluctuation occurs, which disrupts the power supply and has a negative impact on the facility. Therefore, the faulty section should be quickly separated from the power facility, etc. at the initial stage of the fault to minimize the negative impact of the fault.

To this end, devices are installed in transmission and distribution lines and power systems to detect failures in real time and quickly operate circuit breakers when failures occur. Devices used to detect power in transmission and distribution lines and power systems and cut off power when failures occur include protection relays, power management units (PMUs), and power meters.

Protection relays, PMUs, power meters, etc. detect analog voltages in transmission and distribution lines or power systems using current transformers (CTs) and potential transformers (PTs). Then, analog detection voltages are converted into digital values through analog-to-digital converters, and faults in transmission and distribution lines or power systems are diagnosed using intelligent electronic devices.

A protection relay detects various electrical faults and transmits an opening operation signal to a circuit breaker for opening the fault section. In the event of a fault, the protection relay operates the circuit breaker through the relay to open the fault section, thereby protecting the equipment and wiring in the normal section.

The protection relay elements that protect the equipment in these power systems are largely classified into two elements: directional elements and non-directional elements. Non-directional elements do not have a major problem in protecting even if the direction of the instrument current transformer (CT) or start point is incorrect, but directional elements may malfunction or fail to operate.

Currently, various tests and field tests are conducted before supplying power to the protection system, but there is currently no test that can 100% verify the directional protection elements unless current is actually applied in the event of an accident, so there is a limitation that it cannot be known before an accident occurs.

Accordingly, in the relevant technical field, there is a demand for the development of technology to determine whether a protective relay with a directional element is operating before an accident without actually applying current at the time of the accident.

Conventional protection relays detect system power on a signal processing board configured with digital signal processing circuits, selectively distinguish relay elements such as phase, heat, and voltage magnitude changes, and transmit the distinguished relay elements to an arithmetic processing board. Then, the arithmetic processing board performs and calculates a preset relay algorithm to determine an abnormality or failure of the power system. Here, the signal processing board performs preset data communication with the arithmetic processing board to transmit signals for the relay elements of the signal processing board to the arithmetic processing board.

However, as with conventional protection relays, if signals according to relay elements are continuously transmitted from the signal processing board to the operation processing board, it is inevitable that external influences such as electromagnetic interference or noise will occur during the signal transmission process. For this reason, signals transmitted from the signal processing board to the operation processing board are distorted by external influences, and malfunctions may occur as a result.

In this way, since signals for relay elements transmitted from the signal processing board to the operation processing board were processed and analyzed unilaterally in one direction and analyzed for abnormalities and failures, there was a problem in that the consistency of the transmitted signals was not considered.

KR Registered Patent No. 10-1061446 KR Registered Patent No. 10-1634633 KR Registered Patent No. 10-1917057 KR Registered Patent No. 10-1817005 KR Publication Patent No. 10-2017-0104305 KR Registered Patent No. 10-2563470

The present invention, which aims to solve the above problems, has the purpose of improving the operating efficiency of solar power facilities by isolating the panels and distribution panels from overvoltage, undervoltage, overcurrent, frequency fluctuation, etc. of transmission and distribution lines, power systems, specific power facilities, etc. in solar power facilities and implementing remote or automatic recovery during the recovery process.

In particular, the present invention aims to provide a relay system designed to be applied to two inverter facilities in a 110 kW class solar power generation facility.

In order to achieve the above object, the present invention comprises: a relay panel having a main body of a predetermined size; a protection relay configured to sample voltage or current of a transmission and distribution line or power system of a solar power generation facility, measure the operation result data obtained by performing a preset relay algorithm operation using the sampled data as source data, and cut off the system power when an abnormality in the system power is determined through the measurement; A first circuit breaker section comprising: an instrument transformer and an instrument transformer local control panel; wherein the voltage transmitted from each phase of a power line bus is transformed into an instrument voltage by the instrument transformer; and then, under the control of the instrument transformer local control panel, a voltage measurement value (Voltage Measurement) is provided to the protection relay through an instrument transformer test terminal (PTT (PT Test Terminal)) among test terminals set for each phase of the power line bus; and an instrument current transformer and an instrument current transformer local control panel; wherein the current transmitted from each phase of the power line bus is transformed into an instrument voltage by the instrument current transformer; and then, under the control of the instrument current transformer local control panel, a current measurement value (Current Measurement) is provided to the protection relay through an instrument current transformer test terminal (CTT (CT Test Terminal)) among test terminals set for each phase of the power line bus; and when it is determined that an abnormality has occurred in the power line power, the first circuit breaker section cuts off the power supplied to the outside; It is configured to include a second circuit breaker unit for cutting off grid power supplied to an external inverter device when an abnormality in the power of the above power system is determined; and a remote communication module for transmitting a cutting signal depending on whether grid power supplied externally is cut off based on abnormal signals of voltage measurement values and current measurement values detected by the protection relay, and a recovery signal depending on a recovery operation in case of cutting off, to the outside through a wireless communication network or receiving a control command signal from the outside.

In addition, the remote communication module comprises a communication module that operates in one of the wireless communication methods of a WPAN communication module, a WLAN communication module, an RF communication module, a CDMA communication module, a Bluetooth communication module, and a Wi-Fi communication module, and the remote communication module is capable of transmitting a plurality of contact signals, and is applied to solar power facilities that transmit/receive operating signals by configuring unidirectional contact signals equally on the transmitting side and the receiving side.

In addition, the second circuit breaker section is provided with two circuit breakers, each of which is configured to cut off power of the first inverter and the second inverter, and the first inverter and the second inverter are configured as 110 kW class inverters.

The present invention, configured and operated as described above, provides a relay device equipped with a remote communication module, through which a wireless communication function is integrated for a relay system requiring a blocking and recovery function, thereby enabling remote recovery control and automatic recovery, thereby improving the stability and operating efficiency of the equipment.

In addition, the present invention has an advantage of providing a relay device optimized for a 110 kW class power generation facility by applying a relay design required for a 110 kW class solar power generation facility.

Figure 1 is a diagram showing the overall configuration of an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.
Figure 2 is a detailed configuration diagram of an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.
Figure 3 is a detailed configuration diagram of an inverter connection part in an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.

Hereinafter, with reference to the attached drawings, an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention will be described in detail.

Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the attached drawings. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The present invention relates to an automatic recovery relay system having a remote communication function applied to a solar power facility, comprising: a relay panel having a main body of a predetermined size; a protection relay configured to sample voltage or current of a transmission and distribution line or a power system of a solar power generation facility, measure the operation result data obtained by performing a preset relay algorithm operation using the sampled data as source data, and cut off the system power when an abnormality in the system power is determined through the measurement; A first circuit breaker section comprising: an instrument transformer and an instrument transformer local control panel; wherein the voltage transmitted from each phase of a power line bus is transformed into an instrument voltage by the instrument transformer; and then, under the control of the instrument transformer local control panel, a voltage measurement value (Voltage Measurement) is provided to the protection relay through an instrument transformer test terminal (PTT (PT Test Terminal)) among test terminals set for each phase of the power line bus; and an instrument current transformer and an instrument current transformer local control panel; wherein the current transmitted from each phase of the power line bus is transformed into an instrument voltage by the instrument current transformer; and then, under the control of the instrument current transformer local control panel, a current measurement value (Current Measurement) is provided to the protection relay through an instrument current transformer test terminal (CTT (CT Test Terminal)) among test terminals set for each phase of the power line bus; and when it is determined that an abnormality has occurred in the power line power, the first circuit breaker section cuts off the power supplied to the outside; It is configured to include a second circuit breaker unit for cutting off grid power supplied to an external inverter device when an abnormality in the power of the above power system is determined; and a remote communication module for transmitting a cutting signal depending on whether grid power supplied externally is cut off based on abnormal signals of voltage measurement values and current measurement values detected by the protection relay, and a recovery signal depending on a recovery operation in case of cutting off, to the outside through a wireless communication network or receiving a control command signal from the outside.

The automatic recovery relay system having a remote communication function applicable to solar power facilities according to the present invention has the main technical feature of providing an automatic recovery relay system which can improve operation efficiency and enhance the stability of the facility by remotely installing a relay recovery function in a relay system constructed between a relay panel and a distribution board applied to solar power facilities. In particular, the present invention provides a relay device designed to be applicable to a 110 kW class solar power generation facility.

Figure 1 is a diagram showing the overall configuration of an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.

The present invention is largely composed of a relay panel, a protection relay (110) for measuring and detecting abnormal signals of a power system, a test terminal (CTT, PTT) for checking a current system and a voltage system, a first circuit breaker (130), and a remote communication module (200) for providing wireless remote communication.

The relay panel (100) can check whether the protection relay (110) is operating and the current, differential current, and suppression current measurements according to the voltage provided to the application transformer protected by the protection relay (110).

The above protection relay (110) samples the voltage or current of the transmission and distribution lines or power system of the solar power generation facility, and measures the result data of the calculation obtained by performing a preset relay algorithm calculation using the sampled data as source data, and cuts off the power of the system when it determines that an abnormality has occurred in the power of the system.

The above protection relay (110) is equipped with an external instrument transformer and an instrument transformer local control panel, and transforms the voltage transmitted from each phase of the power line bus (Bus) by the instrument transformer into an instrument voltage, and then obtains a voltage measurement value through an instrument transformer test terminal (PTT; 120 (PT Test Terminal)) among the test terminals set for each phase of the power line bus under the control of the instrument transformer local control panel.

FIG. 2 is a detailed configuration diagram of an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.

The above protection relay (110) is equipped with an instrument current transformer and an instrument current transformer local control panel, and transforms the current transmitted from each phase of the power line bus (Bus) by the instrument current transformer into an instrument current, and then obtains a current measurement value (Current Measurement) through an instrument current transformer test terminal (CTT; 120 (CT Test Terminal)) among the test terminals set for each phase of the power line bus according to the control of the instrument current transformer local control panel.

Here, the protective relay (110) that receives the voltage measurement may correspond to an AC overvoltage relay that operates when the AC voltage exceeds the specified value, a ground fault direction relay/power direction relay that operates according to the power and ground fault direction of the AC circuit, and a ground fault direction relay.

In addition, the protective relay (110) that receives the current measurement may include the above-described ground fault directional relay/power directional relay and ground fault directional relay, a short circuit/ground fault selection relay that selects short circuit and ground fault circuit, an AC overcurrent relay that operates on overcurrent, and a neutral point O.C.R.

In addition, the protection relay (110) is preferably a digital protection relay and provides relay elements such as OCR, OCGR, DOCR, DOCGR, SGR, OVR, UVR, OVGR, POR, NSOVR, and NSOCR. In addition, the protection relay may preferably correspond to a digital composite relay that provides high-precision measurement and protection relaying at the same time.

A test terminal (120) is configured, which includes a current transformer test terminal (CTT; Current Transducer Test, hereinafter referred to as “CTT”) for preventing open circuit of the secondary current output signal line of an external main current transformer, and a voltage transformer test terminal (PTT; Potential Transducer Test, hereinafter referred to as “PTT”) for preventing short circuit of the secondary voltage output signal line of an external main voltage transformer that receives voltage of a transmission line system, converts it into a secondary voltage, and outputs it.

The first circuit breaker (MCCB; 130) is a circuit breaker that primarily blocks the output power supplied to the outside.

In addition, the relay system according to the present invention is configured to include a power meter (140) for monitoring the amount of power.

Meanwhile, the remote communication module (200) according to the present invention is a wireless communication module that transmits the operation signal of the protection relay (110) to the outside or receives a command signal from the outside, and may adopt any one of the wireless communication methods of a WPAN communication module, a WLAN communication module, an RF communication module, a CDMA communication module, a Bluetooth communication module, and a Wi-Fi communication module.

The above remote communication module (200) can transmit and receive an operation signal or a command signal through communication between the switchboard and the panel, and when a blocking signal (contact signal) occurs, it can provide a blocking operation signal to the outside or receive a recovery signal from the outside to provide a recovery signal of the circuit breaker. In other words, it can transmit and receive bidirectional contact signals, and it is preferable to configure a remote communication module of the same type on the transmitting side and the receiving side.

Therefore, in the present invention, a relay panel capable of remote communication is configured, and transmission and reception of relay operation signals are implemented through communication with a switchboard or an external terminal (operator terminal), thereby promoting convenience for operators through remote control.

FIG. 3 is a detailed configuration diagram of an inverter connection part in an automatic recovery relay system having a remote communication function applied to a solar power facility according to the present invention.

In the present invention, a relay device optimized for a 110 kW class power generation facility is provided in order to configure a relay system required for a 110 kW class solar power generation facility.

To this end, as shown in Fig. 3, the configuration of the inverter (150) is composed of a first inverter (151) and a second inverter (152), and a 110 kW class inverter is applied to the first inverter (151) and the second inverter (152).

At this time, in the present invention, a second circuit breaker (131) is separately configured to cut off the power supply of the inverter from the relay panel and is configured to cut off the power of the two inverters respectively.

The present invention, configured as described above, provides a relay device equipped with a remote communication module, through which a wireless communication function is integrated into a relay system requiring blocking and recovery functions, thereby enabling remote recovery control and automatic recovery, thereby improving the stability and operating efficiency of the equipment.

In addition, the present invention has an advantage of providing a relay device optimized for a 110 kW class power generation facility by applying a relay design required for a 110 kW class solar power generation facility.

While the present invention has been described and illustrated with reference to preferred embodiments for illustrating the principles of the present invention, it is not intended to be limited to the exact construction and operation as described and illustrated. Rather, it will be readily apparent to those skilled in the art that numerous changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such appropriate changes and modifications and equivalents should be considered to fall within the scope of the present invention.

100 : Relay Panel
110 : Protective relay
120 : Test terminal
130: First block donation
131: Second Block Donation
140 : Power meter
150 : Inverter
200 : Remote communication module

Claims (3)

A relay panel having a body of a predetermined size;
A protection relay configured to sample the voltage or current of a power transmission and distribution line or power system of a solar power generation facility, measure the result data of the calculation obtained by performing a preset relay algorithm calculation using the sampled data as source data, and cut off the power of the system when an abnormality in the power of the system is determined through this;
Equipped with an instrument transformer and an instrument transformer local control panel, the voltage transmitted from each phase of the power line bus is transformed into an instrument voltage by the instrument transformer, and then, under the control of the instrument transformer local control panel, the voltage measurement is provided to the protection relay through the instrument transformer test terminal (PTT (PT Test Terminal)) among the test terminals set for each phase of the power line bus.
Equipped with an instrument current transformer and an instrument current transformer local control panel, the current transmitted from each phase of the power line bus is transformed into an instrument current, and then, under the control of the instrument current transformer local control panel, the current measurement value (Current Measurement) is provided to the above protection relay through the instrument current transformer test terminal (CTT (CT Test Terminal)) among the test terminals set for each phase of the power line bus.
A first circuit breaker that primarily cuts off the grid power supplied externally when an abnormality in the above power grid power is determined;
A second circuit breaker for cutting off the grid power supplied to an external inverter device when an abnormality in the power grid power is determined; and
It is configured to include a remote communication module that transmits a blocking signal according to whether or not the grid power supplied to the outside is blocked based on an abnormal signal of the voltage measurement value and current measurement value detected by the above protection relay and a recovery signal according to the recovery operation in case of blocking to the outside through a wireless communication network or receives a control command signal from the outside;
The above remote communication module,
A communication module that operates in one of the wireless communication methods among a WPAN communication module, a WLAN communication module, an RF communication module, a CDMA communication module, a Bluetooth communication module, and a Wi-Fi communication module is configured.
The above remote communication module can transmit multiple contact signals and is applied to solar power facilities that transmit/receive operating signals by configuring the bidirectional contact signals equally on the transmitting side and the receiving side.
The above second block donation is,
An automatic recovery relay system having a remote communication function applied to a solar power facility, each of which is equipped with two circuit breakers, each of which is configured to cut off power of a first inverter and a second inverter, and wherein the first inverter and the second inverter are composed of 110 kW class inverters. delete delete