KR102158243B1 - Remote circuit breaker monitoring system - Google Patents

Abstract

The present invention relates to a circuit breaker monitoring system capable of remotely monitoring a state of a circuit breaker. According to one aspect of the present invention, the circuit breaker monitoring system comprises: a circuit breaker monitoring device collecting state information of a circuit breaker and transmitting the collected state information of the circuit breaker to a gateway; and a gateway transmitting the state information of the circuit breaker received from the circuit breaker monitoring device to a higher level system.

Description

Remote circuit breaker monitoring system {REMOTE CIRCUIT BREAKER MONITORING SYSTEM}

The present invention relates to a remote circuit breaker monitoring system.

A circuit breaker or an earth leakage circuit breaker is installed in the distribution board or the switchboard to cut off the power supply in case of overcurrent or leakage current. In the case of a circuit breaker or an earth leakage circuit breaker (hereinafter, referred to simply as a'breaker' when special classification is not required), an accessory device can be used to determine the state of the circuit breaker from the outside of the circuit breaker. The accessory device includes, for example, an alarm using an alarm contact (AL), an indicator using an auxiliary contact (AX), or an earth leakage alarm using an earth leakage alarm contact.

However, it is possible to check the state of a breaker through an accessory device only when it is close to the breaker, and in order to determine the state of the breaker in a remote host system, there is a problem in that contact information used by the accessory device must be connected to the upper system by wire.

In addition, if the breaker does not perform the cut-off operation even though an overcurrent or leakage trip condition occurs due to a breakdown in the internal mechanism of the breaker, the overcurrent or leakage trip is reflected in the contact point of the accessory device. There is a problem that you can't know that you didn't.

An object of the present invention is to provide a circuit breaker monitoring system capable of remotely monitoring the state of a circuit breaker.

In addition, an object of the present invention is to provide a breaker monitoring system capable of monitoring malfunction of a breaker due to aging or failure.

In addition, an object of the present invention is to provide a circuit breaker monitoring system that is easy to install because there is no need to connect from a breaker to an upper system by wire in order to transmit the state information of the breaker to the upper system.

In addition, an object of the present invention is to provide a circuit breaker monitoring system that is simple to install and requires less maintenance without disconnection of AC power.

In addition, an object of the present invention is to provide a circuit breaker monitoring system that does not require replacement of the battery and is easy to maintain.

In addition, an object of the present invention is to provide a circuit breaker monitoring system capable of monitoring whether or not a breaker operates normally in an overcurrent situation.

One aspect of the present invention, a circuit breaker monitor for collecting the status information of the breaker, and transmitting the collected status information of the breaker to the gateway; And the gateway for transmitting the status information of the breaker received from the breaker monitor to a higher level system.

In the breaker monitoring system, the breaker monitor includes: a breaker interface for collecting status information of the breaker; An operation unit receiving the breaker status information from the breaker interface and generating a breaker status information packet to be transmitted to the gateway; And a transmission unit receiving the breaker status information packet from the operation unit and transmitting the breaker status information packet to the gateway.

The breaker monitoring system further includes a current transformer coupled to the load-side wire of the breaker, and the breaker monitor further includes an energy harvesting unit for supplying power to the inside of the breaker monitor using the output current of the current transformer. can do.

In the circuit breaker monitoring system, the current transformer may be of a clamp type surrounding the load-side wire of the circuit breaker.

In the circuit breaker monitoring system, the energy harvesting unit may store energy supplied through the output current of the current transformer in a capacitor, and supply the energy stored in the capacitor into the breaker monitor.

In the breaker monitoring system, the energy harvesting unit may not supply power to the inside of the breaker monitor after a predetermined time has elapsed from the blocking operation of the breaker.

In the breaker monitoring system, the breaker interface may collect contact information of an accessory device of the breaker.

In the breaker monitoring system, the contact information collected by the breaker interface may include an alarm contact (AL) and an auxiliary contact (AX).

In the circuit breaker monitoring system, the circuit breaker is an earth leakage circuit breaker, and the contact information collected by the circuit breaker interface may further include an earth leakage alarm contact point (EAL).

In the breaker monitoring system, the breaker interface transmits the breaker status information to the operation unit in an interrupt method, and the operation unit changes from the sleep mode to an active mode when receiving the interrupt from the breaker interface while operating in a sleep mode. Can be.

In the breaker monitoring system, the breaker interface may transmit a trip signal instructing the breaker to perform a breaking operation to the breaker.

In the breaker monitoring system, the operation unit may periodically or aperiodically transmit an alive signal to the upper system through the transmission unit and the gateway.

In the breaker monitoring system, the breaker monitor further includes a current detection unit, the current detection unit detects a magnitude of the load-side current of the breaker from the output current of the current transformer, and the operation unit The overcurrent information determined based on the magnitude information of the load-side current of the circuit breaker may be included in the circuit breaker status information packet and transmitted to the upper system through the transmission unit and the gateway.

In the breaker monitoring system, the transmission unit may transmit the breaker status information packet to the gateway in a one-way communication method.

In the breaker monitoring system, the gateway may transmit and receive data with the upper system in a two-way communication method.

In the breaker monitoring system, the breaker monitor may be spatially separated from the current transformer and disposed.

In the breaker monitoring system, the breaker monitor may be disposed in a case of the current transformer.

In the breaker monitoring system, if the breaker does not perform a breaking operation even though a trip condition of the breaker has occurred, the breaker monitor continues after notifying the upper system that the trip condition of the breaker has occurred By transmitting an alive signal, the upper system can recognize a failure of the breaker.

According to an aspect of the present invention, it is possible to remotely monitor the state of a circuit breaker. In addition, according to an aspect of the present invention, it is possible to monitor malfunction of a circuit breaker due to aging or failure. In addition, according to an aspect of the present invention, installation is simple because there is no need to connect the circuit breaker to the upper system by wire in order to transmit the state information of the circuit breaker to the upper system. In addition, according to an aspect of the present invention, installation is simple without disconnection of the AC power source, and there is little need for maintenance. In addition, according to an aspect of the present invention, there is no need to replace the battery, so maintenance is easy. In addition, according to an aspect of the present invention, it is possible to monitor whether the circuit breaker operates normally in an overcurrent situation.

1 illustrates a circuit breaker monitoring system and a surrounding environment thereof according to an embodiment.
2 illustrates a breaker monitor that can be used in the breaker monitoring system of FIG. 1.
3 illustrates a circuit breaker monitoring system and a surrounding environment thereof according to an embodiment.
4 and 5 each illustrate a breaker monitor that can be used in the breaker monitoring system of FIG. 3.
6 and 7 illustrate a clamp type current transformer according to an embodiment.
8 illustrates an energy harvesting unit according to an embodiment.
9 illustrates the relationship between the state of the circuit breaker and the contact point of the accessory device.
10 illustrates the relationship between the state of the earth leakage circuit breaker and the contact point of the accessory device.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, in describing the constituent elements of the present invention, terms such as first, second, A, B, (a), (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to that other component, but another component between each component It should be understood that elements may be “connected”, “coupled” or “connected”.

1 illustrates a circuit breaker monitoring system 100 and its surrounding environment according to an embodiment of the present invention.

Referring to FIG. 1, the circuit breaker monitoring system 100 may obtain status information of the circuit breaker 30 from the circuit breaker 30 and transmit it to the upper system 40. To this end, the breaker monitoring system 100 may include a breaker monitor 110 and a gateway 120.

The circuit breaker 30 is disposed between the two AC wires 10 and 20 to electrically connect the AC wire 10 and the AC wire 20 under normal operating conditions, and when an abnormal situation such as an overcurrent or a short circuit occurs, an AC wire (10) It is possible to block the electrical connection between the AC wire 20. For example, the AC wire 10 is a power-side wire of a breaker, and the AC wire 20 may be understood as a load-side wire of the breaker.

The upper system 40 may be a system that manages the circuit breaker 30 and its surrounding system. For example, the upper system 40 may be a system that collects and manages information on the circuit breaker 30 and/or the AC wires 10 and 20.

The circuit breaker monitor 110 may collect the state information of the circuit breaker 30 and transmit the collected state information of the circuit breaker to the gateway 120 wirelessly. By allowing the circuit breaker monitor 110 and the gateway 120 to communicate wirelessly, the circuit breaker monitor 110 is installed adjacent to the circuit breaker 30, and the gateway 120 is installed adjacent to the upper system 40 to provide a circuit breaker 30 A wired connection for transferring the status information of) to the upper system 40 may be unnecessary or minimized.

To this end, by way of example, the circuit breaker monitor 110 may include a circuit breaker interface for communicating with the circuit breaker and collecting circuit breaker status information, and a transmitter for wirelessly transmitting the collected circuit breaker status information to the gateway 120. For example, the transmitter of the circuit breaker monitor 110 may use a one-way communication method that only transmits information to the gateway 120 in order to reduce power consumption used for wireless communication with the gateway 120.

For example, the circuit breaker monitor 110 may collect power through inductive coupling with the AC wire 20 without using a battery or the like, and operate using the collected power. In this case, maintenance costs for power supply such as battery replacement of the circuit breaker monitor 110 may be reduced.

For example, the circuit breaker monitor 110 may collect status information of the circuit breaker 30 from the accessory device of the circuit breaker 30. The accessory device of the circuit breaker 30 may include, but is not limited to, an alarm device using an alarm contact, an indicator light using an auxiliary contact, and an earth leakage alarm device using an earth leakage alarm contact.

The gateway 120 may transmit the circuit breaker status information received from the circuit breaker monitor 110 to the upper system 40. For example, the gateway 120 may transmit and receive data with the upper system 40 in a two-way communication method. Communication between the gateway 120 and the upper system 40 may use a general wired or wireless communication method.

2 illustrates a circuit breaker monitor 110 that may be used in the circuit breaker monitoring system 100 of FIG. 1.

Referring to FIG. 2, the circuit breaker monitor 110 may include a circuit breaker interface 111, an operation unit 112, a transmission unit 113, and a power supply unit 114.

The circuit breaker interface 111 may collect status information of the circuit breaker. For example, the circuit breaker interface 111 may collect contact information of a circuit breaker accessory. The contact information of the breaker accessory device collected by the breaker interface 111 may include an alarm contact AL and an auxiliary contact AX. The alarm contact AL is a contact for sounding an alarm through an alarm device when the circuit breaker detects an overcurrent and performs a cut-off operation (overcurrent trip), and may be a contact that turns on when an overcurrent trip. The auxiliary contact AX is a contact used for an indicator light for indicating the normal operation of a breaker, and may be a contact that is turned on when the breaker is in an ON state. When the circuit breaker is an earth leakage circuit breaker, contact information of an accessory device collected by the circuit breaker interface 111 may further include an earth leakage alarm contact point (EAL). The earth leakage alarm contact point (EAL) is a contact point for sounding an alarm through an earth leakage alarm device when the circuit breaker detects a leakage current and performs a cut-off operation (leakage trip), and may be a contact that is turned on during an earth leakage trip.

In this way, the circuit breaker monitor 110 may be able to grasp the state of the circuit breaker by collecting contact information used by the circuit breaker accessory device through the circuit breaker interface 111.

9 illustrates the state of the circuit breaker and the contact point of the accessory device. The contact point of the accessory device may include an alarm contact (AL contact) used by an alarm, etc. and an auxiliary contact (AX contact) used by an indicator light.

The breaker can have three states of on, off, and overcurrent trip, and the breaker interface 111 collects alarm contact (AL contact) and auxiliary contact (AX contact) information, so that the breaker has three You can determine which of the states you are in. Exemplarily, if the alarm contact (AL contact) is on (ON), the breaker is in overcurrent trip state, when the auxiliary contact (AX contact) is on (ON), the breaker is on (ON), and alarm contact (AL contact) When both the and auxiliary contacts (AX contacts) are OFF, it can be understood that the breaker is in the OFF state.

10 illustrates a state of an earth leakage circuit breaker and a contact point of an accessory device. In addition to the alarm contact (AL contact) used by alarms and the auxiliary contact (AX contact) used by indicator lights, the contact point of the auxiliary device of the earth leakage breaker may further include the earth leakage alarm contact (EAL contact) used by the earth leakage alarm device. have.

The earth leakage circuit breaker can have four states of on (ON), off (OFF), overcurrent trip, and earth leakage trip. The circuit breaker interface 111 is an alarm contact (AL contact), an auxiliary contact (AX contact) and an earth leakage alarm contact. By collecting (EAL contact) information, it is possible to determine which of the four states the earth leakage breaker is in. For example, if both the alarm contact (AL contact) and the earth leakage alarm contact (EAL contact) are ON, the earth leakage breaker is in the earth leakage trip state, the alarm contact (AL contact) is ON and the earth leakage alarm contact (EAL contact) When the contact) is OFF, the earth leakage breaker is in overcurrent trip state, and when the auxiliary contact (AX contact) is ON, the breaker is in ON state, alarm contact (AL contact), auxiliary contact (AX contact) And when all of the earth leakage alarm contact points (EAL contact points) are OFF, it may be understood that the circuit breaker is in an OFF state.

In this way, when the circuit breaker monitor 110 collects contact information of an accessory device of the circuit breaker through the circuit breaker interface 111, there is an advantage in that it is possible to accurately grasp the state of the circuit breaker already installed without a power failure. In the upper system, the circuit breaker and the system can be managed using the information collected through the circuit breaker monitor 110.

Referring back to FIG. 2, the breaker interface 111 may transmit a trip signal instructing the breaker to perform a blocking operation to the breaker according to the embodiment. The circuit breaker monitoring system of this embodiment can detect a case where the breaker does not perform a blocking operation due to deterioration of the breaker, etc. even when a trip condition of the breaker occurs (details will be described later), in this case, the breaker interface 111 Through the transmission of a trip signal to the breaker, it is possible to force the breaker to perform a blocking operation.

The circuit breaker interface 111 may transmit the collected circuit breaker status information (CSI) to the operation unit 112. For example, the breaker interface 111 may transmit the breaker status information (CSI) to the operation unit in an interrupt method.

The operation unit 112 obtains the breaker status information (CSI) from the breaker interface 111, generates a breaker status information packet (CSIP), and transmits the breaker status information packet (CSIP) to the upper system through the transmission unit 113 and the gateway. Can be transferred to. The circuit breaker status information packet CSIP transmitted by the operation unit 112 to the upper system may include all or part of the breaker status information collected by the breaker interface 111. A conventional processor may be used for the operation unit 112. A memory may be used together with the operation unit 112 as necessary to perform a storage function.

Exemplarily, the circuit breaker interface 111 transmits the circuit breaker status information (CSI) to the operation unit 112 in an interrupt method, and the operation unit 112 receives an interrupt signal from the circuit breaker interface 111 while operating in the sleep mode normally. Then, it is changed from the sleep mode to the active mode to generate a breaker status information packet (CSIP) and transmit it to the transmitter 113. In this way, when the operation unit 112 and the circuit breaker interface 111 transmit information in an interrupt manner, the operation unit 112 operates in a sleep mode during normal operation, thereby reducing power consumption.

The operation unit 112 may, for example, periodically or aperiodically transmit an alive signal to an upper system through the transmission unit 113 and the gateway. The alive signal transmitted by the operation unit 112 to the upper system may be understood as a signal indicating to the upper system that the circuit breaker monitoring system is operating normally.

The transmitter 113 may receive a breaker status information packet (CSIP) from the operation unit 112 and transmit a breaker status information packet (CSIP) to the gateway. For example, the transmission unit 113 may transmit a breaker status information packet (CSIP) to the gateway in a wireless communication method. For example, the transmitter 113 may transmit a breaker status information packet (CSIP) to the gateway in a one-way communication method. Here, the one-way communication method may be understood to mean that the transmission unit 113 only transmits information to the gateway and does not receive information from the gateway. When the transmission unit 113 uses a one-way communication method, power consumption of the transmission unit 113 may be reduced.

The power supply unit 114 may supply power (Vcc) required by the circuit breaker interface 111, the operation unit 112, and the transmission unit 113 inside the circuit breaker monitor 110. For example, the power supply unit 114 may include a battery. For example, the power supply unit 114 may further include a regulator for converting the battery voltage into a voltage required inside the circuit breaker monitor 110 in addition to the battery. The breaker monitor 110 may be directly electrically connected to the load-side wire of the breaker to receive power, but in this case, there is a problem that the AC power must be cut off.

In this way, the breaker monitoring system of this embodiment collects the status information of the breaker through the breaker interface 111 and wirelessly transmits the breaker status information to the gateway through the transmission unit 113, so that a breaker monitor disposed adjacent to the breaker ( 110) to a remote host system through an electric wire can eliminate the inconvenience.

In addition, the breaker interface 111 transmits the breaker status information (CSI) to the operation unit 112 using an interrupt method, and the transmission unit 113 transmits a breaker status information packet (CSIP) to the gateway in a one-way communication method, It is possible to reduce the power consumption of the circuit breaker monitor 110. Since the circuit breaker monitor 110 is installed adjacent to the circuit breaker and is difficult to receive power from the outside, reducing the power consumption of the circuit breaker monitor 110 can be a great advantage. For example, when the power supply unit 114 uses a battery, reducing the power consumption of the circuit breaker monitor 110 may increase the battery replacement cycle, thereby reducing maintenance costs. As an example, as will be described later, when the circuit breaker monitor 110 collects and uses power by itself using an energy harvesting unit without using a battery, the power collected through the energy harvesting unit may not be sufficient, so the circuit breaker Reducing the power consumption of the monitor 110 may be more important.

3 illustrates a circuit breaker monitoring system 300 and its surrounding environment according to an embodiment.

Referring to FIG. 3, the circuit breaker monitoring system 300 is different from that illustrated in FIG. 2 in that it further includes a current transformer 330.

The current transformer 330 is fastened to the load-side wire 20 of the circuit breaker 30 and may output a current having a size corresponding to the size of the current flowing through the load-side wire 20 to the circuit breaker monitor 110. For example, the current transformer 330 may use a method of magnetically coupling with the load-side electric wire 20.

According to an embodiment, the current transformer 330 may be a clamp type surrounding the load-side wire 20 of the circuit breaker 30. 6 and 7 illustrate a clamp type current transformer 330.

Referring to FIG. 6, the current transformer 330 includes an upper portion 330a and a lower portion 330b, and the upper portion 330a and the lower portion 330b are connected at one side by a fastening means such as a hinge. Can be

Referring to FIG. 7, the upper portion 330a and the lower portion 330b of the current transformer 330 may be coupled to each other so as to have an inner diameter through which the electric wire 20 can pass. Illustratively, the current transformer 330 is implemented in the form of a clamp, by opening one side of the inner diameter and inserting the load-side wire 20 of the circuit breaker into the inner diameter and then closing one side of the inner diameter, so that the current transformer ( 330) may be installed.

For example, the current transformer 330 may include a winding (not shown) to generate a current using a magnetic field derived from an AC current flowing through the load-side wire 20 of the circuit breaker. Through this, the current transformer 330 may output a current having a magnitude corresponding to the magnitude of the current flowing through the load-side wire 20.

Referring back to FIG. 3, the circuit breaker monitor 310 may be spatially separated from the current transformer 330 and disposed in a separate case. Alternatively, according to an embodiment, the circuit breaker monitor 310 may be disposed in the case of the current transformer 330. In this case, since both the current transformer 330 and the circuit breaker monitor 310 disposed adjacent to the circuit breaker 30 are accommodated in the case of the current transformer 330 as illustrated in FIG. 6, the structure can be simplified and the installation can be simple. .

4 and 5 illustrate breaker monitors 410 and 510 that can be used in the breaker monitoring system of FIG. 3, respectively.

Referring to FIG. 4, the circuit breaker monitor 410 is different from the circuit breaker monitor 110 illustrated in FIG. 2 in that it further includes an energy harvesting unit 414.

The energy harvesting unit 414 may supply power to the inside of the circuit breaker monitor 410 using the output current of the current transformer. To this end, the energy harvesting unit 414 stores energy supplied through the output current of the current transformer in a capacitor (not shown), and supplies the power stored in the capacitor to the inside of the circuit breaker monitor 410 through a power supply (Vcc) line. I can. Various circuits (operation unit 112, transmission unit 113, circuit breaker interface 111, etc.) inside the circuit breaker monitor 410 may operate using power (Vcc) provided from the energy harvesting unit 414.

8 illustrates an energy harvesting unit 814 according to an embodiment.

Referring to FIG. 8, the energy harvesting unit 814 may include a rectifier 8141, a capacitor Cs and a regulator 8142.

In FIG. 8, two magnetically coupled windings 820 and 831 are shown, the winding 820 may be understood as the load-side wire 20 of the circuit breaker 30 illustrated in FIG. 3, and the winding 831 ) May be understood as a winding provided inside the current transformer 330. That is, the winding 831 of the current transformer 330 is magnetically coupled to the load-side wire 20 of the circuit breaker 30, and when an AC current flows through the load-side wire 20 of the circuit breaker 30, the winding 831 of the current transformer 831 In ), a current having a magnitude corresponding to the magnitude of the current flowing through the load-side wire 20 of the circuit breaker 30 may be induced. The energy harvesting unit 814 may collect energy by using the current output from the winding 831 of the current transformer.

The rectifier 8141 may rectify the current output from the winding 831 of the current transformer and transmit it to the capacitor Cs. For example, the rectifier 8141 may perform bidirectional rectification using a conventional bridge-type diode or a unidirectional rectifier circuit, but the present embodiment is not limited thereto.

The capacitor Cs may be charged using the current received from the rectifier 8141 to store energy. The energy stored in the capacitor Cs may cause the circuit breaker monitor to operate for a predetermined time even after the circuit breaker is cut off. That is, after the breaker's blocking operation, the breaker monitor may transmit information that an overcurrent or trip condition has occurred in the breaker by using the energy stored in the capacitor Cs to the upper system. After that, if the energy stored in the capacitor Cs becomes insufficient, the circuit breaker monitor may stop itself.

The regulator 8142 may change the magnitude of the voltage supplied from the capacitor Cs and provide it to the inside of the circuit breaker monitor. The voltage of the capacitor Cs may vary in magnitude according to the current induced from the winding 831 of the current transformer, and the regulator 8142 converts and stabilizes the fluctuating voltage of the capacitor Cs to generate a power supply (Vcc). And can be provided inside the breaker monitor. A typical switching power conversion device (SMPS) or a low drop-out (LDO) regulator may be used as the regulator 8142, but the present embodiment is not limited thereto. The regulator 8142 may not be used when the voltage range in which the circuit breaker monitor internal circuits can operate is wide.

Referring back to FIGS. 3 and 4, when the energy harvesting unit 414 collects power using the current induced from the current transformer 330 coupled to the load-side wire 20 of the circuit breaker 30, the circuit breaker 30 After the blocking operation of ), the energy harvesting unit 414 cannot collect power. Therefore, after a predetermined time has elapsed from the blocking operation of the circuit breaker 30, the energy harvesting unit 414 will not supply power to the inside of the circuit breaker monitor. Here, the predetermined time may be understood as a time during which the circuit breaker monitor 310 can operate using the power already stored in the energy harvesting unit 414.

In this way, the circuit breaker monitor 410 according to the present embodiment may not require a separate power supply means such as using a battery or supplying power by wire, by using the energy harvesting unit 414. This can be a significant advantage in terms of installation and maintenance of the circuit breaker monitor 410.

In addition, the circuit breaker monitor 410 according to the present embodiment has an advantage that can be easily installed without disconnection of AC power by using a clamp type current transformer.

In addition, the circuit breaker monitor 410 according to the present embodiment may have an advantage of detecting an internal failure of the circuit breaker 30. For example, there may be a case in which the breaker 30 does not perform a blocking operation in a situation in which an overcurrent trip or an earth leakage trip occurs due to an aging or internal failure of the breaker 30. In this case, the circuit breaker monitor 410 of the present embodiment, as described above, detects that an overcurrent or an earth leakage trip has occurred from the contact information of the circuit breaker accessory device and transmits it to the upper system 40. Thereafter, if the circuit breaker 30 operates normally and performs the blocking operation, the circuit breaker monitor 410 does not receive power from the load-side wire 20. Therefore, when a predetermined time elapses after the blocking operation of the circuit breaker, the circuit breaker monitor 410 ) Should stop the operation, but if the breaker 30 fails to perform the blocking operation due to obsolescence or failure of the breaker 30, the breaker monitor 410 continues to receive power through the energy harvesting unit 414 Will continue to work. The breaker monitor 410 notifies the upper system 40 whether or not the upper system 40 performs a normal operation by periodically or aperiodically transmitting an alive signal to the upper system 40. In the upper system 40, even after receiving information that an overcurrent or an earth leakage trip condition has occurred from the breaker monitor 410, if the alive signal from the breaker monitor 410 is continuously received, the breaker 30 is overcurrent or It can be seen that there is a problem in that the blocking operation cannot be performed even in a situation in which an earth leakage trip occurs.

In this way, even though the tripping situation of the breaker 30 occurs, if the breaker 30 does not perform the blocking operation due to the aging or failure of the breaker 30, the breaker monitor 410 is the upper system and the breaker 30 After notifying that the trip condition of the has occurred, an alive signal is continuously transmitted to the upper system, so that the upper system can recognize the failure of the breaker 30.

That is, by using the energy harvesting unit 414 that collects energy through the current transformer 330 fastened to the circuit breaker 30, the load-side wire 20, the circuit breaker monitor 410 only in the ON state of the breaker 30 When power is supplied to the circuit breaker monitor 410 to operate, and when the circuit breaker 30 performs a blocking operation, power is not supplied to the circuit breaker monitor 410 and the circuit breaker monitor 410 automatically stops operating. Since it operates in a manner, the operation of the breaker monitor 410 itself can be used as one piece of information to determine whether the breaker 30 has failed.

As described above, the advantages of using the energy harvesting unit 414 are various. However, it needs to be considered that the amount of power collected through the energy harvesting unit 414 may not be sufficient. Therefore, it is preferable that the circuit breaker monitor 410 reduces the power consumed inside.

To this end, the transmission unit 113 of the present embodiment may communicate with the gateway using a one-way communication method. When the transmission unit 113 uses a one-way communication method compared to a case where the gateway and the two-way communication method are used, the transmission unit 113 transmits data to the gateway only when necessary, and can operate in a sleep mode when not necessary. Power consumption of the transmitter 113 can be reduced.

In addition, when the circuit breaker interface 111 transmits the circuit breaker status information (CSI) to the operation unit 112, an interrupt method may be used. In this case, the operation unit 112 operates in a sleep mode during normal operation and reduces power consumption. When an interrupt signal is received from the circuit breaker interface 111, the operation unit 112 operates by changing to an activation mode, thereby reducing power consumption of the operation unit 112.

As described above, the circuit breaker monitor 410 according to the present embodiment is configured to use the energy harvesting unit 414 by reducing power consumption as much as possible, thereby utilizing the advantages of the energy harvesting unit 414.

Referring to FIG. 5, the circuit breaker monitor 510 is different from the circuit breaker monitor 410 illustrated in FIG. 4 in that it further includes a current detection unit 515.

The current detection unit 515 may detect the magnitude (Irms) of the load-side current of the breaker from the output current of the current transformer and transmit it to the operation unit 112. For example, the operation unit 112 may include information on the magnitude (Irms) of the load-side current of the breaker in the breaker status information packet CSIP and transmit the information to the upper system through the transmission unit 113 and the gateway. Depending on the embodiment, the operation unit 112 determines whether overcurrent flows through the circuit breaker through information on the magnitude (Irms) of the load-side current on the circuit breaker, instead of transmitting information on the magnitude (Irms) of the load-side current of the breaker to the upper system. Information on whether or not can be transmitted to the upper system. According to an embodiment, the current detection unit 515 determines whether there is an overcurrent using information on the magnitude (Irms) of the load-side current of the breaker, and when it is determined as an overcurrent, it notifies the operation unit 112 of the occurrence of the overcurrent in an interrupt method, and the operation unit ( 112) can transmit the overcurrent information to the upper system upon receiving the overcurrent information through the interrupt signal. In this case, there is an advantage of reducing power consumption of the operation unit 112.

In this way, when transmitting the current magnitude (Irms) information or overcurrent information on the load side of the breaker to the upper system, the upper system will determine whether or not a normal overcurrent trip occurs at the contact point of the circuit breaker's accessory device in the overcurrent situation, and the breaker normally shuts off in the overcurrent situation. You can determine whether to perform an action.

Terms such as "include", "consist of", or "have" described above, unless otherwise stated, mean that the corresponding component may be included, and thus other components are not excluded. It should be interpreted as being able to further include other components. All terms, including technical or scientific terms, unless otherwise defined, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms generally used, such as terms defined in the dictionary, should be interpreted as being consistent with the meaning in the context of the related technology, and are not interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

Claims (18)

A circuit breaker monitor collecting status information of a breaker and transmitting the collected status information of a breaker to a gateway;
A current transformer coupled to the load-side wire of the breaker; And
Including; the gateway for transmitting the status information of the breaker received from the breaker monitor to the upper system,
The circuit breaker monitor,
A breaker interface for collecting status information of the breaker;
An operation unit receiving the breaker status information from the breaker interface and generating a breaker status information packet to be transmitted to the gateway;
A transmission unit for receiving the breaker status information packet from the operation unit and transmitting the breaker status information packet to the gateway in a one-way communication method; And
It includes an energy harvesting (energy harvesting) unit for supplying power to the inside of the circuit breaker monitor by using the output current of the current transformer,
The breaker monitor operates by power supplied from the energy harvesting unit without using a battery,
The energy harvesting unit does not supply power to the inside of the breaker monitor after a predetermined time has elapsed from the blocking operation of the breaker,
When a trip condition of the breaker occurs, the operation unit notifies that the trip condition of the breaker has occurred to the upper system through the transmission unit and the gateway, and the breaker does not perform a blocking operation even though the trip condition of the breaker occurs. When the energy is supplied through the energy harvesting unit even after the predetermined time has elapsed, an alive signal is transmitted to the upper system so that the upper system can recognize a failure of the circuit breaker. Circuit breaker monitoring system. delete delete The method according to claim 1,
The current transformer is a circuit breaker monitoring system, characterized in that the clamp type surrounding the load-side wire of the breaker. The method according to claim 1,
The energy harvesting unit stores energy supplied through the output current of the current transformer in a capacitor, and supplies the energy stored in the capacitor to the inside of the breaker monitor. delete The method according to claim 1,
The breaker interface is a breaker monitoring system, characterized in that collecting contact information of the accessory device of the breaker. The method of claim 7,
The contact information collected by the breaker interface includes an alarm contact (AL) and an auxiliary contact (AX). The method of claim 8,
The circuit breaker is an earth leakage circuit breaker,
The contact information collected by the breaker interface further includes an earth leakage alarm contact point (EAL). The method according to claim 1,
The breaker interface transmits the breaker status information to the operation unit in an interrupt method,
The circuit breaker monitoring system, wherein the operation unit is changed from the sleep mode to an active mode when receiving the interrupt from the breaker interface while operating in the sleep mode. The method according to claim 1,
The breaker interface is a circuit breaker monitoring system, characterized in that for transmitting a trip signal instructing the breaker to perform a breaking operation to the breaker. delete The method according to claim 1,
The breaker monitor further includes a current detection unit,
The current detection unit detects the magnitude of the load-side current of the breaker from the output current of the current transformer,
The operation unit includes the overcurrent information determined based on the magnitude information of the load-side current of the breaker or the magnitude information of the load-side current of the breaker in the breaker status information packet and transmits the information to the upper system through the transmission unit and the gateway Circuit breaker monitoring system. delete delete delete The method of claim 4,
The circuit breaker monitoring system, characterized in that disposed in the case of the clamp type of the current transformer. delete

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