KR101510046B1 - Apparatus for monitoring and managing electric power and method for processing sensor signal using the same - Google Patents

Abstract

According to disclosed embodiments, provided is a device for monitoring and managing power. The device comprises: multiple sensor modules which are installed in respective breakers to generate sensor signals; a main controller to transmit at least one control signal to each of the sensor modules to receive synthetic sensor signals representing the sensor signals generated by the sensor modules in a separate starting point, to analyze the sensor signals based on the synthetic sensor signals, and to control power supply from the breakers; a sensor signal line which is commonly connected to the sensor modules and is connected to the main controller to be used to transmit the synthetic sensor signals to the main controller; and a control communication line which is commonly connected to the sensor modules and is connected to the main controller to be used to transmit at least one control signal to each of the sensor modules, thereby realizing simple and efficient power monitoring and management.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for monitoring and managing power, and a sensor signal processing method using the same. [0002]

The disclosed embodiments relate to power monitoring and management techniques, and more particularly to power monitoring and management techniques that optimize the number of lines from multiple sensors providing sensor signals and also facilitate the analysis of sensor signals. do.

A distribution board is used to provide direct current (DC) or alternating current (AC) power to the branch towards the electrical machine by appropriately distributing power from a commercial power source. Typically, the distribution board includes a branch breaker for controlling power supply to each branch. When the branch circuit breaker is provided with a current sensor, a voltage sensor and / or a leakage current sensor, an EMS (Energy Management System) for improving the utilization efficiency of electric power provided through the distribution board detects the current, voltage and / It is possible to calculate various information related to power quality, electric safety, power management, etc., based on the leakage current, and to cause the branch circuit breaker or the relay device connected thereto to cut off power flowing into the branch if necessary. Power monitoring and management devices that implement such systems may be required for power-consuming household, industrial, or other diverse applications. Particularly, along with the development of IT technology, diversification of such devices is actively performed, such as adding a function of monitoring consumed electric power and transmitting the electric power to an external terminal and / or a server through a network.

However, according to the conventional distribution panel related technology, as the number of branches increases, the number of required sensors increases and the number of sensor signal lines connecting such a large number of sensors to the controller of the distribution board increases sharply. Therefore, a distribution board having a large number of branches has a complicated structure, low productivity, and high frequency of occurrence of faults. Further, such a distribution panel requires a large number of circuits for signal processing, so that the number of signal inputs in the controller and the volume of the controller as well as the volume of the distribution box itself increase. Further, when the number of signal inputs of the controller is smaller than the total number of sensor signal lines, another controller for accommodating a number of signal lines exceeding at least the number of signal inputs must be adopted, And / or installation of another controller to send to the server. Therefore, in order to manufacture an existing distribution board, it is necessary to consider complicated operations such as addition of a controller and change of software due to the possibility of expansion of a branch and its extension. Therefore, there is a need for a technique that can optimize the arrangement of the sensor lines and secure the easiness of signal processing in order to solve the above problem caused by an increase in the number of branches.

The disclosed embodiments provide a signaling network for transmitting sensor signals from each of the sensors in a corresponding time interval, a technique for analyzing signals transmitted by time period, and a transmission of control signals for controlling the transmission of sensor signals between these time periods And provides a power monitoring and management technique that utilizes a communication network for communication.

According to an exemplary embodiment, there are provided a plurality of sensor modules, each sensor module being provided in a circuit breaker and generating a sensor signal; Transmitting at least one control signal to each of the plurality of sensor modules to receive a composite sensor signal representing the sensor signal from each of the plurality of sensor modules in a distinct time interval, A main controller for analyzing the signal and controlling power supply from the breaker; A sensor signal line commonly connected to the plurality of sensor modules and connected to the main controller and used to transmit the composite sensor signal to the main controller; And a control communication line commonly connected to the plurality of sensor modules and connected to the main controller and used to transmit the at least one control signal to each of the plurality of sensor modules, Is provided.

Each of the plurality of sensor modules sensing a current, a voltage and a short circuit and generating the sensor signal to indicate a result of the sensing; And a sensor controller for connecting the sensor signal generated by the sensor to the sensor signal line or disconnecting the sensor signal line from the sensor signal line so that the composite sensor signal is received at the main controller.

The sensor controller includes: a communication unit for communicating a control signal with the main controller; A switching unit; And a microcontroller for causing the switching unit to connect the sensor signal to the sensor signal line or disconnect the sensor signal from the sensor signal line based on the control signal received from the main controller .

The microcontroller may also cause the communication unit to transmit another control signal to the main controller via the control communication line and the other control signal may indicate that the sensor signal is connected to the sensor signal line, It may indicate that the sensor signal is disconnected from the sensor signal line.

The main controller includes a control unit for transmitting to the specific sensor module via the control communication line a first control signal for instructing to connect the sensor signal from the specific one of the plurality of sensor modules to the sensor signal line And the sensor controller of the particular sensor module may couple the sensor signal from the particular sensor module to the sensor signal line in response to receiving the first control signal.

The controller may also identify the identifier of the specific sensor module to transmit the first control signal to the specific sensor module.

The sensor controller may also transmit a second control signal via the control communication line to the control unit indicating that the sensor signal from the specific sensor module is connected to the sensor signal line, In response to receiving the control signal, obtain information used to control power supply from the breaker equipped with the specific sensor module based on the sensor signal from the specific sensor module.

The main controller also analyzes the sensor signal from the specific sensor module for the acquisition of the information and further includes at least one of a current, voltage, leakage current, power, harmonics, overcurrent, overvoltage, THD (Total Harmonic Distortion) And a measurement and analysis unit for acquiring information on the measurement result.

The main controller may further include a plurality of external communication units, and each of the plurality of external communication units may transmit the obtained information to an external computing device via a network conforming to a different communication protocol.

The control unit may also determine, based on the obtained information, whether the sensor signal from the specific sensor module is to be continuously connected to the sensor signal line.

The control unit may further transmit to the specific sensor module via the control communication line a third control signal instructing to disconnect the sensor signal from the sensor signal line from the specific sensor module, The sensor controller may disconnect the sensor signal from the specific sensor module from the sensor signal line in response to receiving the third control signal.

According to another exemplary embodiment, each of the sensor modules is provided with a sensor signal line commonly connected to a plurality of sensor modules provided in the circuit breaker and generating sensor signals, and a main controller connected to a control communication line commonly connected to the plurality of sensor modules A method of processing a sensor signal, the method comprising: transmitting a first control signal to the specific sensor module via the control communication line, the first control signal instructing to connect a sensor signal from a specific one of the plurality of sensor modules to the sensor signal line; Receiving from the specific sensor module via the control communication line a second control signal indicating that the sensor signal from the specific sensor module is connected to the sensor signal line; And acquiring information used to control power supply from a circuit breaker equipped with the specific sensor module based on the sensor signal from the specific sensor module in response to receipt of the second control signal. A sensor signal processing method is provided.

The sensor signal from the specific sensor module may indicate a result of sensing one of a current, a voltage, and a short circuit.

The sensor signal processing method may further include confirming an identifier of the specific sensor module to transmit the first control signal to the specific sensor module.

Wherein the acquiring step analyzes the sensor signal from the specific sensor module and acquires information on at least one of a current, a voltage, a leakage current, a power, a harmonic, an overcurrent, an overvoltage, a total harmonic distortion (THD) Step < / RTI >

The sensor signal processing method may further include transmitting the obtained information to an external computing device via a plurality of networks conforming to different communication protocols.

The sensor signal processing method may further include determining whether the sensor signal from the specific sensor module is to be continuously connected to the sensor signal line based on the obtained information.

The sensor signal processing method further includes transmitting a third control signal via the control communication line to the specific sensor module instructing to disconnect the sensor signal from the sensor signal line from the specific sensor module can do.

According to yet another exemplary embodiment, there is provided a computer readable storage medium having stored thereon a computer program for executing the method.

Certain embodiments provide an improved technique for implementing devices that perform simple and efficient power monitoring and management.

According to certain embodiments, a plurality of sensors (e.g., current sensors, voltage sensors, and / or leakage current sensors) are applied to each branch in a distribution board including a plurality of power branches (connected by a branch breaker) The number of lines connecting the sensors and the distribution board controller can be greatly reduced.

According to some embodiments, a power monitoring and management system is provided that facilitates the analysis of signals from the sensors while simultaneously optimizing the number of signal lines from the sensors to the distribution board controller.

According to some embodiments, the distribution board controller can simplify the signal processing circuit and reduce the volume.

According to some embodiments, even if the number of power branches is increased, a separate controller for adding the controller, changing the line harness, changing the software, and transmitting information from the various controllers to the external server and / Installation is not required.

According to the predetermined embodiment, productivity improvement and cost reduction of the EMS for maximizing the utilization efficiency of the power consumption and the apparatus for monitoring and managing the power for implementing the EMS can be expected.

Figure 1 illustrates an apparatus for power monitoring and management in accordance with an exemplary embodiment;
2 is a diagrammatic illustration of an example of a composite sensor signal delivered to a main controller in accordance with an exemplary embodiment,
3 shows a sensor module according to an exemplary embodiment,
4 illustrates a process for controlling transmission of a sensor signal from a sensor module according to an exemplary embodiment;
5 shows a main controller according to an exemplary embodiment,
6 is a diagram illustrating a process for processing a sensor signal received by a main controller according to an exemplary embodiment;
7 is a diagram schematically illustrating the structure of a control signal between a main controller and each sensor module according to an exemplary embodiment;

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. The following detailed description is provided to provide a comprehensive understanding of the methods, apparatus, and / or systems described herein. However, this is merely an example and the present invention is not limited thereto.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification. The terms used in the detailed description are intended only to describe embodiments of the invention and should in no way be limiting. Unless specifically stated otherwise, the singular forms of the expressions include plural forms of meanings. In this description, the expressions "comprising" or "comprising" are intended to indicate certain features, numbers, steps, operations, elements, parts or combinations thereof, Should not be construed to preclude the presence or possibility of other features, numbers, steps, operations, elements, portions or combinations thereof.

Figure 1 illustrates an apparatus for power monitoring and management in accordance with an exemplary embodiment.

An exemplary power monitoring and management device 100 includes a plurality of sensor modules 110-1 through 110-n, a main controller 120 and a plurality of different lines communicatively coupled to the main controller 120 Sensor signal line 130, control communication line 140, and power line 150).

The main controller 120 may be electrically connected to one or more circuit breakers (e.g., a DC branch circuit breaker and / or an AC branch circuit breaker) in the distribution board. A predetermined circuit breaker (e.g., a main circuit breaker) in the distribution board can supply or block applied power (e.g., AC power applied from a commercial power source) to another circuit breaker (e.g., AC branch circuit breaker). In addition, the main controller 120 may receive power (e.g., AC power) from a particular circuit breaker. Some circuit breakers in the distribution board may have one or more sensor modules such as sensor modules 110-1, 110-2, ..., 110-n. The main controller 120 can acquire various information based on the sensor signal from the sensor module provided in the circuit breaker, and can control the operation of the circuit breaker based on the obtained information. For example, some circuit breakers in the distribution board may be electrically connected to the electrical device and may supply or block the electrical device under the control of the main controller 120. According to some embodiments, the breaker may be coupled to the relay device, and the main controller 120 may control operation of the relay device to allow the relay device to control the power supply from the circuit breaker. According to some alternative embodiments, the main controller 120 may directly control the operation of the breaker to cause it to be powered or disconnected from the breaker.

The main controller 120 controls each of the sensor modules 110-1 to 110-n so as to receive the synthesized sensor signals representing the sensor signals from the respective sensor modules 110-1, 110-2, ..., 110- 110-1, 110-2, ..., 110-n based on the synthesized sensor signal, and can transmit at least one control signal to each of the sensor modules 110-1, 110-2, ..., 110- n) and to control the power supply from the breaker. For example, the main controller 120 may obtain the information necessary to control the power supply from the circuit breaker equipped with the sensor module based on the sensor signal from the specific sensor module in a specific time period. The main controller 120 may also transmit the acquired information to an external computing device, such as a server, smart phone, or other communication terminal, over a network following one or more different communication protocols.

Each of the plurality of sensor modules 110-1 to 110-n is configured to generate a predetermined sensor signal. For example, each of the sensor modules 110-1, 110-2, ..., 110-n may be a breaker provided with the sensor modules 110-1, 110-2, ..., 110- Sensor signals used to indicate or derive electrical information such as current, voltage, leakage current, power, harmonics, overcurrent, overvoltage, THD (total harmonic distortion) and / Can be provided. Thus, the information obtained from the sensor signal may include information related to power quality (e.g., THD), information related to electrical safety (e.g., arc, leakage current, overcurrent, overvoltage) and / / RTI > and / or power, current, voltage, etc. associated with power monitoring). Each sensor module 110-1, 110-2, ..., 110-n is also configured to transmit a sensor signal to the main controller 120. [ The sensor signal lines 130 are commonly connected to the plurality of sensor modules 110-1 to 110-n and are connected to the sensor modules 110-1, 110-2, ..., and 110-n, The sensor signal may be transmitted to the main controller 120 via the sensor signal line 130.

The transmission of the sensor signal may be performed under the control of the main controller 120. For example, each sensor module 110-1, 110-2, ..., 110-n may send a sensor signal in response to receiving a control signal from the main controller 120 via the control communication line 140 And may be connected to or disconnected from the sensor signal line 130. Accordingly, by transmitting at least one appropriate control signal from the main controller 120 to the sensor modules 110-1, 110-2, ..., 110-n via the control communication line 140, It is possible to transmit a signal to the main controller 120 through the sensor signal line 130. [ According to some embodiments, for the generation of this composite sensor signal, a control signal that instructs to connect a sensor signal from a specific one of the sensor modules 110-1 through 110-n to the sensor signal line 130 (Hereinafter also referred to as "connection command signal") may be transmitted to the sensor module. In addition to transmitting this connection command signal, another sensor module (in particular, a sensor module to which the sensor signal was connected to the sensor signal line 130) is instructed to disconnect the sensor signal from the sensor signal line 130 A control signal (hereinafter also referred to as "disconnection command signal") may be transmitted. After receiving the sensor signal from the sensor module receiving the connection command signal, the main controller 120 may process the sensor signal to acquire various information. The obtained information can be used to control the power supply from the breaker equipped with the sensor module. The main controller 120 may determine whether to continue transmitting the sensor signal from the sensor module or transmit the sensor signal from another sensor module based on the obtained information, and may transmit an appropriate control signal if necessary. 2 schematically illustrates an example of a synthesized sensor signal transmitted to the main controller 120. As shown in FIG. 2, a sensor signal from each of the sensor modules 110-1, 110-2, ..., 110-n has a separate duration duration 210 -1, 210-2, ..., 210-n. (A switching section 221 immediately after the sustain section 210-1, a sustain section 210 after the sustain section 210-1, and a sustain section 210 immediately after the sustain section 210-1) in which a sensor module connected to the sensor signal line 130 is connected, -2) and the switching section 229 immediately before the sustain section 210-n).

In some embodiments, the sensor signals and control signals between each sensor module 110-1, 110-2, ..., 110-n and the main controller 120 may each appear as a voltage of a predetermined level. In some other embodiments (e.g., where each sensor module 110-1, 110-2, ..., 110-n and main controller 120 are separated by a predetermined distance or more), each sensor module 110- 1, 110-2, ..., 110-n and the main controller 120 may be represented by currents of predetermined levels, respectively.

1, each of the plurality of lines 130, 140, and 150 is shown as one line commonly connected to the sensor modules 110-1 to 110-n and connected to the main controller 120, There may be additional lines commonly connected to the main controllers 120-1 to 110-n and coupled to the main controller 120 and paired with each line. For example, the sensor signal line 130 and the additional sensor signal lines paired therewith may be a high level voltage / current sensor signal line and a low level voltage / current sensor signal line, respectively. The difference in voltage / current flowing through these sensor signal lines can indicate the sensor signal. Likewise, the control communication line 140 and the additional control communication line paired therewith may be a high level voltage / current control communication line and a low level voltage / current control communication line. The difference in voltage / current flowing through these control communication lines may represent a control signal. The power line 150 may also be paired with a ground line.

The sensor signal line 130 constitutes one network (hereinafter also referred to as a "signal network") together with the sensor modules 110-1 to 110-n and the main controller 120 connected thereto As described above, one synthesized sensor signal integrated with sensor signals output from the sensor modules 110-1 through 110-n can be transmitted to the main controller 120 on the network. In addition, the control communication line 140 can be seen as constituting another network (hereinafter also referred to as a "communication network") together with the sensor modules 110-1 to 110- Control signals for controlling the output of the sensor signals of the sensor modules 110-1 to 110-n are transmitted from the main controller 120 to the sensor modules 110-1 to 110-n on that network As described above. This communication network can be used to perform communication of various other data and / or control signals between the sensor modules 110-1 to 110-n and the main controller 120 in addition to the control of the above signal network. According to some embodiments, the communication network may be based on serial communication according to the RS485 protocol or the CAN protocol. 1, the power line 150 includes sensor modules 110-1 through 110-n for distributing power from the main controller 120 to the sensor modules 110-1 through 110-n, n.

By employing the sensor signal line 130, the control communication line 140, and the power line 150, the number of lines input to the main controller 120 can be significantly reduced compared to conventional distribution boards. For example, in a conventional distribution panel, when 32 current sensors and 32 leakage sensors are respectively connected to a pair of signal lines for transmitting sensor signals from the sensor and each pair of signal lines is connected to the distribution board controller separately, A total of 128 signal lines are inserted into the distribution board controller, except for the power lines. However, in an exemplary power monitoring and management device 100, instead of the above 128 signal lines, the sensor signal line 130 and the sensor signal line paired therewith, and the control communication line 140 and its A control communication line paired with the control communication line may be input to the main controller 120. As such, the device 100 for power monitoring and management can minimize the number of lines for a number of power branches through interworking of the signal network and the communication network. Therefore, in the process of producing the apparatus 100 for monitoring and managing power, it is possible to reduce the labor of processing a large number of input lines and to alleviate the burden of adding a controller even when the number of power branches increases sharply . In addition, the main controller 120 can transmit at least one control signal to the sensor modules via the communication network and receive the composite sensor signal (e.g., shown in FIG. 2) over the signal network, ) Can analyze sensor signals from each sensor module using precise and various timing charts. Accordingly, it is not necessary to increase the number of signal processing circuits in the main controller 120 even if the number of sensor modules to be connected to the main controller 120 surges. Furthermore, the apparatus 100 for monitoring and managing power, including the main controller 120 and the main controller 120, as compared with the conventional distribution panel, can be small in volume.

Figure 3 shows a sensor module according to an exemplary embodiment.

Each of the above-mentioned sensor modules 110-1, 110-2, ..., 110-n may include an exemplary sensor module 300. [ As shown in FIG. 3, the sensor module 300 includes a sensor 310 and a sensor controller 320.

In some embodiments, the sensor 310 may be configured to sense one of current, voltage, and leakage, and to generate a sensor signal indicative of the sensed result. For example, the sensor 310 may be a current sensor, a voltage sensor, or a leakage current sensor provided in the branch breaker, and generates a sensor signal indicating a result of detecting a current, a voltage, can do. Accordingly, the electricity-related information can be obtained from the branch current value, the branch voltage value, or the branching leakage current value provided from the sensor 310. The sensor 310 may be operated in a similar manner when it is equipped with other types of breakers.

The sensor controller 320 is configured to connect the sensor signal to the sensor signal line 130 or disconnect it from the sensor signal line 130. Such connection and disconnection may enable one composite sensor signal to be communicated to the main controller 120. [ In addition, the sensor controller 320 may store device information of the sensor controller 320, which includes information on the function of the sensor module 300, for example, information indicating that the sensor 310 is a voltage sensor can do. The above device information may be stored in a storage medium such as a non-volatile memory within the sensor controller 320. Alternatively or additionally, the sensor controller 320 may include a DIP switch for setting such device information.

3, the sensor controller 320 may include a switching unit 321, a communication unit 323, a microcontroller 325, a connector 327, and a power supply unit 329. As shown in FIG.

The connector 327 is connected to ports for connecting the sensor module 300 to each of a plurality of lines (e.g., sensor signal line 130, control communication line 140 and power line 150) Ports, control communication line ports, and power line ports, etc.). The dotted lines shown in FIG. 3 indicate the connectivity to the corresponding line through each port of the connector 327.

The switching unit 321 may include a switching circuit for connecting or disconnecting the sensor signal from the sensor 310 to the sensor signal line 130. For example, the switching unit 321 may send a sensor signal to the sensor signal line port of the connector 327 to introduce the sensor signal generated by the sensor 310 into the sensor signal line 130.

The communication unit 323 can perform communication of control signals and / or data (e.g., RS485 protocol or serial communication according to the CAN protocol) via the control communication line 140. [ For example, such control signals and / or data may be transmitted / received to / from the control communication line 140 via the control communication line port of the connector 327.

The microcontroller 325 may be configured to control the operation of other components of the sensor controller 320 (e.g., the switching unit 321 and the communication unit 323). For example, the microcontroller 325 can receive a control signal, such as a connection command signal or a connection release command signal, input from the main controller 120 to the communication unit 323 from the communication unit 323, So that the switching unit 321 can perform the connection or disconnection of the sensor signal. The microcontroller 325 may also generate various other data and / or control signals and cause the communication unit 323 to transmit the generated data and / or control signals to the main controller 120 ). ≪ / RTI > As an example, when it is determined that the sensor signal output from the sensor 310 and connected to the sensor signal line 130 has stabilized to a predetermined level or a predetermined time has elapsed after the connection of such sensor signals, the microcontroller 325 ) May generate a control signal (hereinafter also referred to as "connection completion signal") indicating that the sensor signal is connected to the sensor signal line 130. As another example, the microcontroller 325 may cause the sensor signal output from the sensor 310 to be disconnected from the sensor signal line 130, and then output a control signal (hereinafter referred to as " Quot;). ≪ / RTI > As another example, the microcontroller 325 can determine whether an error has occurred during transmission of the sensor signal output from the sensor 310 to the main controller 120. If it is determined that an error has occurred It is possible to generate error information indicating this. The main controller 120 may use the above-described control signals to detect which sensor is connected to the main controller 120 or to obtain information on the operating state of such a sensor.

The power supply unit 329 converts the power input from the power line 150 to the power line port of the connector 327 and supplies the converted power to the other components of the sensor controller 320 (for example, the switching unit 321, the communication unit 323, (E.g., a microcontroller 325, etc.), for example, a DC / DC converter.

4, an exemplary process 400 for controlling the transmission of sensor signals from the sensor module 300 is described below.

In operation S410, the sensor controller 320 receives a connection command signal from the main controller 120 via the control communication line 140. [

In operation S420, in response to receiving the connection command signal, the sensor controller 320 connects the sensor signal generated by the sensor 310 to the sensor signal line 130. [ The sensor signal may be transmitted to the main controller 120 via the sensor signal line 130.

In operation S430, the sensor controller 320 determines whether an error has occurred in the transmission of the sensor signal.

If it is determined that no error has occurred, the process 440 proceeds to operation S440. In operation S440, when the sensor controller 320 determines that the output sensor signal is stable to a predetermined level or after a preset time elapses, the sensor controller 320 transmits a connection completion signal to the main controller 120 via the control communication line 140. [ Lt; / RTI >

In operation S450, the sensor controller 320 waits for a disconnection command signal to be received from the main controller 120 via the control communication line 140. [

If a disconnect command signal is received, the process 400 proceeds to operation S460. In operation S460, the sensor controller 320 disconnects the sensor signal from the sensor signal line 130, thereby blocking the sensor signal from the sensor 310 from being transmitted through the sensor signal line 130. [ In addition, the sensor controller 320 may send a disconnection complete signal to the main controller 120 via the control communication line 140.

On the other hand, if it is determined in operation S430 that an error has occurred, the process 400 proceeds to operation S435. In operation S435, the sensor controller 320 transmits error information indicating the occurrence of an error to the main controller 120 via the control communication line 140. [ Then, the process 400 proceeds to operation S460.

After operation S460 is performed, process 400 may be performed in a similar manner for other sensor modules.

5 shows a main controller according to an exemplary embodiment.

5, the exemplary main controller 120 includes a control unit 510, a measurement and analysis unit 520, at least one external communication unit 530-1 to 530-j, and a power supply unit 540 .

The main controller 120 is connected to the sensor modules (e.g., the sensor modules 110-1 to 110-n) via the sensor signal line 130 as a node of the signal network, And is connected to the sensor modules through a control communication line 140 as a node of the network. The control unit 510 is configured to receive the sensor signals from the sensor modules via the signal network and exchange control signals and / or necessary data with the sensor modules via the communication network. The power required for these sensor modules is provided from the power supply 540 through the power line 150. In some embodiments, the power supply 540 may include circuitry, such as an AC / DC converter, coupled to the AC power source and for converting and transferring the AC power introduced therefrom to the sensor modules.

The control unit 510 is also configured to control the operation of other components of the main controller 120 (e.g., the measurement and analysis unit 520 and the external communication units 530-1 to 530-j). Accordingly, the control unit 510 obtains predetermined information (for example, information used to control power supply from the breaker equipped with the sensor module) based on the sensor signal from the specific sensor module, 560-i (e.g., a server, smartphone, and / or other communication terminal) coupled to the at least one external computing device 560-1, ..., 560-i.

The measurement and analysis unit 520 may be used to obtain information based on the sensor signal. As an example, the measurement and analysis unit 520 analyzes the sensor signal from a specific sensor module based on the synthesized sensor signal and determines the current, voltage, leakage current, power, harmonic, overcurrent, overvoltage, THD and / May be configured to obtain the same electrical information. Analysis of the sensor signal performed in the measurement and analysis unit 520 may include converting the sensor signal to a digitized signal. In some embodiments, the control unit 510 may use the acquired information to block power to the electronic device or other breaker associated with the breaker.

Each of the external communication units 530-1, 530-2, ..., 530-j receives all or a part of the obtained electric-related information and / or environment-related information, and transmits the received information to the external communication unit 530- ..., 550-j corresponding to the external computing devices 560-1, 530-2, ..., 530-j through the networks 550-1, 550-2, 560-i and receives data and / or control signals from the computing devices 560-1, ..., 560-i and forwards them to the control unit 510 and / or the measurement and analysis unit 520 . In some embodiments, the various external communication units 530-1 through 530-j may receive the same information, and each corresponding network 550-1, 550-2, ... 550- You can transfer it through. In some other embodiments, the various external communication units 530-1 to 530-j may receive different information and transmit it to the outside.

Different communication protocols may be applied to each network 550-1, 550-2, ..., 550-j. Examples of such protocols may include Bluetooth, Ethernet, Wi-Fi, ZigBee, CDMA, PLC, RS485 and CAN protocols. The device information of the external communication units 530-1, 530-2, ..., 530-j may be stored in each of the external communication units 530-1, 530-2, ..., 530- This device information may include information indicating a communication protocol to be followed by the external communication units 530-1, 530-2, ..., 530-j. The device information may be stored in a storage medium such as a non-volatile memory in the external communication units 530-1, 530-2, ..., 530-j. Alternatively, or additionally, each of the external communication units 530-1, 530-2, ..., 530-j may include a dip switch for setting such device information.

The operation of the control unit 510 according to some embodiments is as follows. In order to receive the sensor signal from the specific sensor module, the control unit 510 confirms the identifier and / or device information of the sensor controller of the sensor module and transmits a connection command signal to the sensor module through the communication network. Thereafter, when receiving the connection completion signal from the sensor module through the communication network, the controller 510 processes the sensor signal received from the sensor module. For example, the control unit 510 transmits the received sensor signal to the measurement and analysis unit 520, and supplies the measurement and analysis unit 520 with predetermined information (e.g., electrical information) from the received sensor signal . The controller 510 then analyzes the acquired information and, based on the analysis results, determines whether the sensor signal from the sensor module is to be continuously connected to the sensor signal line 130 or the sensor module to receive the sensor signal Can be determined. If it is determined that it is necessary to process the sensor signal from another sensor module, the control unit 510 may transmit a disconnection command signal through the communication network to the sensor module that is currently transmitting the sensor signal through the signal network .

Also, the control unit 510 can configure and manage the signal network and the communication network. For example, the control unit 510 assigns a unique identifier to each of the sensor modules (for example, the sensor modules 110-1 to 110-n) connected to the main controller 120 through the signal network and the communication network can do. In some embodiments, the control unit 510 can detect the device information of the sensor module from each sensor module, and determine the identifier of the sensor module based on the detected device information. In addition, when a new sensor module is added to the signaling network and the communication network, the control unit 510 may assign an identifier to the sensor module in a similar manner. The controller 510 may store the identifier and / or device information of each sensor module. Further, when a sensor module is separated from the signal network and the communication network, the control unit 510 can automatically recognize such separation and delete the identifier and / or device information of the sensor module. In this way, the control unit 510 can maintain the identifier and / or device information of each sensor module for configuration and management of the signal network and the communication network. If necessary, the controller 510 may send the stored identifier and / or device information to the sensor modules and / or other components of the main controller 120 (e.g., (E.g., external communication units 530-1 to 530-j).

Similarly, the control unit 510 may assign an identifier unique to each of the external communication units 530-1, 530-2, ..., 530-j. Similar to the approach discussed above with respect to the sensor module, the control unit 510 maintains the identifier and / or device information of each external communication unit 530-1, 530-2, ..., 530-j, (E.g., external communication units 530-1 through 530-j) and / or sensor modules associated with the main controller 120 of the base station 120.

6, an exemplary process 600 for processing sensor signals received by main controller 120 is described below.

In operation S610, the main controller 120 includes sensor modules (e. G., Sensor modules (e. G., Sensor modules) commonly connected to both the sensor signal line 130 and the control communication line 140 110-1 to 110-n) of the sensor module in order to receive the sensor signal from the specific sensor module for a specific time period.

In operation S620, the main controller 120 transmits a connection command signal to the upper sensor module via the control communication line 140. [ A sensor signal from the upper sensor module may be connected to the sensor signal line 130 according to a connection command signal. Accordingly, the main controller 120 can receive the sensor signal through the sensor signal line 130. [

In operation S630, the main controller 120 waits for the connection completion signal to be received from the upper sensor module via the control communication line 140. [

When the connection completion signal is received, the process 600 proceeds to operation S640. In operation S640, the main controller 120 processes the received sensor signal. Through the processing of such a sensor signal, the information used to control the power supply from the breaker equipped with the upper sensor module can be obtained. According to some embodiments, the main controller 120 may transmit the obtained information to an external computing device via multiple networks conforming to different communication protocols.

In operation S650, the main controller 120 transmits a disconnection command signal to the upper sensor module via the control communication line 140. [ For example, based on the result of the sensor signal processing performed in operation S640, the main controller 120 may now determine that the processing of the sensor signal from the other sensor module is necessary, and in this case, Signal can be transmitted.

In operation S660, the main controller 120 waits for a disconnection complete signal from the upper sensor module via the control communication line 140. [

If a disconnection complete signal is received, process 600 may be resumed at operation S610 for another sensor module.

7 is a diagram schematically illustrating a structure of a control signal between a main controller and each sensor module according to an exemplary embodiment.

7, the exemplary control signal 700 includes a Tx_MID field 710, an Rx_MID field 720, an Rx_SID field 730, a PID field 740, a data payload 750, and a CheckSum field 760). The Tx_MID field 710 indicates the type of controller to which the control signal 700 is sent and the Rx_MID field 720 indicates the type of controller to which the control signal 700 is received. For example, the values of each of the Tx_MID field 710 and the Rx_MID field 720 may include (i) a sensor module such as "100" (ii) sensor module 330 indicating a main controller such as the main controller 120 (Iii) when a sensor module such as the sensor module 330 includes a voltage sensor, if the sensor module includes a current sensor, "110 ", which indicates a sensor controller included in the sensor module, (iv) when a sensor module such as the sensor module 330 includes a leakage current sensor, a sensor module such as "112" or (v) a sensor module 330 indicating a sensor controller included in the sensor module, And may be "113" indicating the sensor controller included in the sensor module, if included. The Rx_SID field 730 indicates an identifier assigned to the controller on which the control signal 700 is received. For example, the identifier may be an integer between 0 and 255. The PID field 740 is a parameter identifier indicating the function of the control signal 700. For example, the PID field may be set to a value of "1" when (i) control signal 700 transfers the identifier of a given controller to another controller, (ii) (Iii) a value of "3" when the control signal 700 requests device information of a predetermined controller, (iv) a value of "3" when the control signal 700 is A value of "4" in the case of providing device information of a predetermined controller, and (v) a value of "5" in the case of indicating that an error occurs in the transmission of the sensor signal by the control signal 700 . The data payload 750 contains the actual data that it wishes to transmit via the control signal 700. The length of the data payload 750 may be predetermined or variable. The CheckSum field 760 is used to check whether an error has occurred in the transmission of the control signal 700. [

On the other hand, certain embodiments may include a computer-readable recording medium including a program for performing the procedures described herein on a computer. The computer-readable recording medium may include a program command, a local data file, a local data structure, or the like, alone or in combination. The media may be those specially designed and constructed for the present invention. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floppy disks, and ROMs, And hardware devices specifically configured to store and execute the same program instructions. Examples of program instructions may include machine language code such as those generated by a compiler, as well as high-level language code that may be executed by a computer using an interpreter or the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, . Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100: Devices that monitor and manage power
110-1, 110-2, ..., 110-n: sensor module
120: main controller

Claims (19)

A plurality of sensor modules respectively provided in the circuit breaker and generating sensor signals;
Transmitting at least one control signal to each of the plurality of sensor modules to receive a composite sensor signal representing the sensor signal from each of the plurality of sensor modules in a distinct time interval, A main controller for analyzing the signal and controlling power supply from the breaker;
A sensor signal line commonly connected to the plurality of sensor modules and connected to the main controller and used to transmit the composite sensor signal to the main controller; And
And a control communication line commonly connected to the plurality of sensor modules and connected to the main controller and used to transmit the at least one control signal to each of the plurality of sensor modules.
Devices that monitor and manage power. The method according to claim 1,
Wherein each of the plurality of sensor modules includes:
A sensor for sensing one of a current, a voltage and a short circuit and generating the sensor signal to indicate a result of the sensing; And
And a sensor controller for connecting the sensor signal generated by the sensor to the sensor signal line or disconnecting the sensor signal line from the sensor signal line so that the composite sensor signal is received at the main controller.
Devices that monitor and manage power. The method of claim 2,
The sensor controller includes:
A communication unit for communicating a control signal with the main controller;
A switching unit; And
And a microcontroller for causing the switching unit to connect the sensor signal to the sensor signal line or disconnect the sensor signal from the sensor signal line based on a control signal received from the main controller.
Devices that monitor and manage power. The method of claim 3,
The microcontroller also causes the communication unit to transmit another control signal to the main controller via the control communication line and the other control signal indicates that the sensor signal is connected to the sensor signal line, Is disconnected from the sensor signal line,
Devices that monitor and manage power. The method of claim 2,
The main controller includes a control unit for transmitting to the specific sensor module via the control communication line a first control signal for instructing to connect the sensor signal from the specific one of the plurality of sensor modules to the sensor signal line ,
Wherein the sensor controller of the specific sensor module connects the sensor signal from the specific sensor module to the sensor signal line in response to receiving the first control signal,
Devices that monitor and manage power. The method of claim 5,
Wherein the controller further identifies an identifier of the specific sensor module to transmit the first control signal to the specific sensor module,
Devices that monitor and manage power. The method of claim 5,
Wherein the sensor controller further transmits a second control signal to the control unit via the control communication line, the second control signal indicating that the sensor signal from the specific sensor module is connected to the sensor signal line,
Wherein the control unit is further adapted to obtain information used to control power supply from a circuit breaker equipped with the specific sensor module based on the sensor signal from the specific sensor module in response to receiving the second control signal,
Devices that monitor and manage power. The method of claim 7,
The main controller also analyzes the sensor signal from the specific sensor module for the acquisition of the information and further includes at least one of a current, voltage, leakage current, power, harmonics, overcurrent, overvoltage, THD (Total Harmonic Distortion) Further comprising a measurement and analysis section for acquiring information on the < RTI ID = 0.0 >
Devices that monitor and manage power. The method of claim 7,
The main controller further includes a plurality of external communication units, each of the plurality of external communication units transmitting the obtained information to an external computing device via a network conforming to a different communication protocol,
Devices that monitor and manage power. The method of claim 7,
The control unit may also determine whether to continue to connect the sensor signal from the particular sensor module to the sensor signal line based on the obtained information,
Devices that monitor and manage power. The method of claim 5,
Wherein the control unit further transmits to the specific sensor module via the control communication line a third control signal instructing to disconnect the sensor signal from the sensor signal line from the specific sensor module,
Wherein the sensor controller of the specific sensor module disconnects the sensor signal from the specific sensor module from the sensor signal line in response to receiving the third control signal,
Devices that monitor and manage power. A sensor signal processing method performed by a main controller connected to a sensor signal line commonly connected to a plurality of sensor modules provided in a circuit breaker and generating sensor signals and a control communication line commonly connected to the plurality of sensor modules,
Transmitting a first control signal through the control communication line to the specific sensor module, the first control signal instructing to connect a sensor signal from a specific one of the plurality of sensor modules to the sensor signal line;
Receiving from the specific sensor module via the control communication line a second control signal indicating that the sensor signal from the specific sensor module is connected to the sensor signal line; And
Acquiring information used to control power supply from a circuit breaker equipped with the specific sensor module based on the sensor signal from the specific sensor module in response to receiving the second control signal.
A method of processing a sensor signal. The method of claim 12,
Wherein the sensor signal from the specific sensor module is indicative of a result of sensing one of a current,
A method of processing a sensor signal. The method of claim 12,
Further comprising identifying an identifier of the specific sensor module to transmit the first control signal to the specific sensor module.
A method of processing a sensor signal. The method of claim 12,
Wherein the acquiring step analyzes the sensor signal from the specific sensor module and acquires information on at least one of current, voltage, leakage current, power, harmonics, overcurrent, overvoltage, THD (total harmonic distortion) ≪ / RTI >
A method of processing a sensor signal. The method of claim 12,
And transmitting the obtained information to an external computing device via a plurality of networks conforming to different communication protocols.
A method of processing a sensor signal. The method of claim 12,
Further comprising determining whether the sensor signal from the particular sensor module will remain connected to the sensor signal line based on the obtained information.
A method of processing a sensor signal. The method of claim 12,
Further comprising transmitting a third control signal via the control communication line to the specific sensor module instructing to disconnect the sensor signal from the sensor signal line from the specific sensor module.
A method of processing a sensor signal. A computer-readable storage medium having stored thereon a computer program for executing the method recited in any one of claims 12 to 18.

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