JP3224750U - Current monitoring system and current output monitoring device - Google Patents

Abstract

The present invention provides a current output monitoring device that quickly adjusts the total power output of a plurality of power generation devices, is low in cost, and can be easily installed. A current output monitoring device includes a control module, a communication module, a first hub module, a second hub module, current sensor modules 105A to 105D, and a switch module. The current sensor module is electrically connected to the second hub module, and the switch module is electrically connected to the first hub module. The switch module is disposed between the plurality of power generation devices and the power collection device, and is electrically connected. The current sensor module is arranged on one side close to the current collector, and detects a plurality of current values from a plurality of power generators. The control module is communicably connected to the server via the communication module, receives the modulated signal, and adjusts the switching module on or off based on the modulated signal. [Selection] Figure 2

Description

  The present invention relates to a current monitoring system and a current output monitoring device, and more particularly, to a current monitoring system and a current output monitoring device controlled by a remote server.

  Traditional photovoltaic power plants do not have IoT-related equipment, and existing equipment cannot respond quickly to the demands of electric power companies for modulation of energy in each area of the power grid. If the equipment is changed to a new one to cope with it, there is a risk that the existing equipment will not fit well in terms of power monitoring.

  Therefore, it is an important task for the industry to provide a current monitoring system that can quickly adjust the total amount of power output of a plurality of power generation devices, is low in cost, and can be easily installed.

  The problem to be solved by the present invention is to provide a current output monitoring device that can quickly adjust the total amount of power output of a plurality of power generation devices, is low in cost, and can be easily installed in response to the lack of existing technology. To provide.

  The current output monitoring device according to the present invention is electrically connected to a plurality of power generation devices and current collection devices. The current output monitoring device includes a control module, a communication module electrically connected to the control module, a first hub module electrically connected to the control module, and an electrical connection to the control module. A second hub module, a current sensor module electrically connected to the second hub module, and a switch module electrically connected to the first hub module. The switch module is electrically connected to the plurality of power generators and the current collector. The switch module is disposed between the plurality of power generation devices and the power collection device. The current sensor module is arranged on one side close to the power collection device, and is used to detect a plurality of current values by the plurality of power generation devices. In particular, the control module is communicably connected to a server via the communication module and receives a modulated signal from the server. The control module adjusts the switch module on or off based on the modulation signal, thereby determining the total amount of power output that the plurality of power generators output to the current collector.

  Another technical measure adopted by the present invention to solve the above technical problem is to provide the following current monitoring system. The current monitoring system is communicatively connected to a server. The current monitoring system includes four power generation devices, a current output monitoring device electrically connected to the four power generation devices, and a current collector. The current output monitoring device includes: a control module; a communication module electrically connected to the control module and the server; a first hub module electrically connected to the control module; A second hub module connected to the second hub module, a current sensor module electrically connected to the second hub module, and a switch module having four switch units. The four switch units in the switch module are electrically connected to the first hub module. The power collection device is electrically connected to the current output monitoring device to transmit power from the four power generation devices to a power grid system. In particular, the four switch units are electrically connected to the four power generators. The four switch units in the switch module are each electrically connected to the current collector by four power lines. The four switch units in the switch module are respectively arranged between the four power generators and the current collector. The four current sensors are respectively arranged outside the four power lines. The current monitoring system adjusts to turn on or off the four switch units of the switch module in the current output monitoring device based on power supply information from the server.

One of the beneficial effects of the present invention is that the current monitoring system and the current output monitoring device provided by the present invention can effectively adjust the total power output based on the power supply information. Further, the current output monitoring device according to the present invention can be simply arranged between the plurality of power generation devices and the power grid system, so that the arrangement cost can be effectively reduced.

FIG. 1 is a schematic diagram illustrating a current monitoring system according to a first embodiment of the present invention. It is a schematic diagram which shows the current output monitoring device of FIG. FIG. 2 is a schematic diagram illustrating power supply information provided by a server in FIG. 1. FIG. 4 is a schematic diagram illustrating a current monitoring system according to a second embodiment of the present invention.

  For a better understanding of the features and technical contents of the present invention, reference will be made to the detailed description of the present invention and the accompanying drawings. However, the attached drawings are provided for reference and explanation only, and are not intended to limit the scope of the claims of the present invention.

  Hereinafter, embodiments of the “current monitoring system and current output monitoring device” disclosed in the present invention will be described with specific examples. Those skilled in the art can understand the advantages and effects of the present invention from the disclosure of the present specification. The present invention can be implemented or applied according to other different embodiments. Each subsection in this specification can be equally modified and changed based on various viewpoints or applications without departing from the scope of the present invention. In addition, the drawings of the present invention are intended to simply and schematically explain, and do not show actual dimensions. In the following embodiments, technical matters according to the present invention will be further described, but the disclosed contents do not limit the present invention.

[First Embodiment]
The current monitoring system 1 is communicably connected to the server 9. The current monitoring system 1 is electrically connected to a power grid system 2. The current monitoring system 1 includes a current output monitoring device 10, a power collection device 11, and a power generation device group 12. The power generation device group 12 includes four power generation devices such as a first solar panel power generation device 121, a second solar panel power generation device 122, a third solar panel power generation device 123, and a fourth solar panel power generation device 124. In the present embodiment, the power generation device group 12 may include various types of power generation devices, such as a solar panel power generation device, a fuel cell power generation device, a wind power generation device, a hydraulic power generation device, a geothermal power generation device, a thermal power generation device, and a biomass power generation device. The present invention is not limited to these examples, including a device, a marine power plant, or a nuclear power plant. The power collection device 11 collects power from a plurality of power generation devices in the power generation device group 12 and performs modulation such as current superposition or voltage adjustment so as to output AC power to the power network system 2.

  In the present embodiment, the current output monitoring device 10 includes a current collector 11, a first solar panel power generator 121, a second solar panel power generator 122, a third solar panel power generator 123 in the power generator group 12, and It is electrically connected to the fourth solar panel power generator 124.

  The current output monitoring device 10 includes a control module 100, a communication module 101, a first hub module 102, a second hub module 103, a switch module 104, a current sensor module 105, a power supply module 106, a protection element 107, and an environment sensor module. 108.

  The control module 100 is electrically connected to the communication module 101, the first hub module 102, the second hub module 103, and the environment sensor module 108. The first hub module 102 is electrically connected to the switch module 104. The second hub module is electrically connected to the current sensor module 105. The communication module 101 is a wired communication module or a wireless communication module. In the present embodiment, the communication module 101 is communicably connected to the server 9. Examples of the communication module include a Wi-Fi (registered trademark) communication module, a Bluetooth (registered trademark) communication module, a ZigBee (registered trademark) communication module, a LoRa communication module, a Sigfox (registered trademark) communication module, and an NB-IoT communication module. However, the present invention is not limited to these examples. The first hub module 102 and the second hub module 103 include an RS232 serial control module or an RS485 serial control module.

  In the present embodiment, the current sensor module 105 includes four current sensors 105A to 105D. The switch module 104 includes four switch units 104A-104D. The switch module 104 includes a first switch unit 104A, a second switch unit 104B, a third switch unit 104C, and a fourth switch unit 104D. The current sensor module 105 includes a first current sensor 105A, a second current sensor 105B, a third current sensor 105C, and a fourth current sensor 105D. The four switch units 104A-104D in the switch module 104 are electrically connected to the first hub module 102. The current sensors 105A to 105D are electrically connected to the second hub module 103. In the present embodiment, the switch units 104A to 104D include an electromagnetic switch or a reed switch, but the present invention is not limited to these examples. The switch units 104A-104D are powered by the first hub module 102. The current sensors 105A-105D are powered by the second hub module 103.

  The current output monitoring device 10 further includes a housing (not shown). The material of the housing may be metal, plastic or rubber, but the present invention is not limited to these examples. Further, in the current output monitoring device 10, the control module 100, the communication module 101, the first hub module 102, the second hub module 103, the switch module 104, the current sensor module 105, the power supply module 106, and the protection element 107 are located inside the housing. Placed in

  The environment sensor module 108 is arranged at a predetermined position other than the housing, and is used to detect an environment parameter. The environmental parameters include a temperature value, a humidity value, an environmental luminance value, and the like. That is, the environment sensor module 108 includes at least one of a temperature sensor, a humidity sensor, and an environment brightness sensor, but the present invention is not limited to these examples. The current collector 11 is electrically connected to the switch module 104 of the current output monitoring device 10.

  The four switch units 104A-104D in the switch module 104 are electrically connected to the four power generators 121-124, respectively. The four switch units 104A to 104D in the switch module 104 are electrically connected to the current collector 11 through four power lines L1 to L4, respectively. The four switch units 104A to 104D in the switch module 104 are arranged between the four power generators 121 to 124 and the current collector 11, respectively. The four current sensors 105A to 105D are arranged outside the four power lines L1 to L4, respectively. In the present embodiment, the current sensors 105A to 105D are Hall sensors, respectively, and detect respective current values on the power lines L1 to L4 by electromagnetic induction.

  The control module 100 is a central processing unit (Central Processing Unit, CPU) or a microprocessor (Microprocessor), but the present invention is not limited to these examples. The server 9 is a remote server or a local server. The server 9 is communicably connected to the regional power management center and is configured to receive power supply information. The server 9 converts the power supply information into a modulated signal and transmits the modulated signal to the current output monitoring device 10.

  In the present embodiment, the power supply module 106 is electrically connected to the control module 100 and the AC power supply AC in order to supply drive current to the current output monitoring device 10. Power supply module 106 is an AC / DC voltage converter. In another embodiment, power supply module 106 may be a DC / DC voltage converter. That is, the power supply module 106 may be connected to a DC power supply.

  Further, since the current output monitoring device 10 is disposed outdoors, a protection element 107 is further disposed between the power supply module 106 and the AC power supply AC to prevent a lightning strike, an overcurrent input, or other accidents. In the present embodiment, the protection element 107 is a breaker. In this embodiment, each of the power generators 121-124 may further be electrically connected to the power storage device to store power.

  Please refer to FIG. FIG. 3 is a schematic diagram showing power supply information by the server of FIG. In particular, it includes the total amount of power output in different time zones on different dates.

  The control module 100 is communicably connected to the server 9 via the communication module 101, and receives a modulation signal from the server 9. The control module 100 adjusts the switch module on or off based on the modulation signal from the server 9, thereby determining the total amount of current output from the plurality of power generation devices 121 to 124 to the power collection device 11. That is, the control module 100 determines the total power output based on the modulation signal provided by the server 9 and the magnitude of the current value detected by the current sensors 105A to 105D of the current sensor module 105. That is, the control module 100 records the maximum current value output by each power generation device, and thereby determines the maximum total power output by the power generation devices 121 to 124 electrically connected to the switch module 104. As such, the control module 100 detects a plurality of current values and modulation signals by the current sensors 105A-105D of the current sensor module 105, and turns on or off the switch units 104A-104D, and correspondingly converts the modulation signals into modulation signals. The corresponding power output is output.

  In the present embodiment, the power generation devices 121 to 124 connected to the current output monitoring device 10 may be different power generation devices, and thus may have power generation states with different conditions. The current output monitoring device 10 records the maximum current value and the minimum current value output from each of the power generation devices 121 to 124, and also records the environmental parameters detected by the environment sensor module 108 in the same time zone. The control module 100 transmits the above environment parameters to the server 9 by the communication module 101 as a basis of the big data analysis.

[Second embodiment]
Please refer to FIG. FIG. 4 is a schematic diagram illustrating a current monitoring system according to a second embodiment of the present invention.

  In the present embodiment, the current monitoring system 5 includes a current collector 51, a power generator group 52, and N current output monitoring devices 50-1 to 50-N. The N current output monitoring devices 50-1 to 50-N include a first current output monitoring device 50-1, a second current output monitoring device 50-2 to an Nth current output monitoring device 50-N. . The power generation device group 52 includes a plurality of power generation devices (not shown). Examples of the power generation device (not shown) include a solar panel power generation device, a fuel cell power generation device, a wind power generation device, a hydroelectric power generation device, a geothermal power generation device, a thermal power generation device, a biomass power generation device, a marine power generation device, or a nuclear power generation device. However, the present invention is not limited to these examples. In the present embodiment, each of the current output monitoring devices 50-1 to 50-N can be connected to one to four power generation devices. That is, the total amount of current output by each of the current output monitoring devices 50-1 to 50-N may be different. The power received by the current output monitoring devices 50-1 to 50 -N is sent to the power collection device 51, further adjusted, and then sent to the power grid system 2.

Each of the current output monitoring devices 50-1 to 50-N is communicably connected to the server 9, and is configured to receive respective power supply information. That is, the server 9 determines the power supply information for each of the current output monitoring devices 50-1 to 50-N based on the power generation status (current value) of the power generation device connected to the current output monitoring devices 50-1 to 50-N. It has become.
[Beneficial Effects of Embodiment]

  One of the beneficial effects of the present invention is that the current monitoring system and the current output monitoring device provided by the present invention can effectively modulate the total power output according to the power supply information. In addition, the current output monitoring device of the present invention can be easily disposed between the plurality of power generation devices and the power grid system, so that the cost related to the distribution can be effectively reduced.

  The contents disclosed above are only preferred embodiments of the present invention, and do not limit the scope of the utility model registration claims of the present invention. All equivalent technical modifications made on the basis of this shall be included in the claims of the present invention.

1, 5: current monitoring system 2: power grid system 9: server 10: current output monitoring device 11, 51: power collection device 12: power generation device group 121: first solar panel power generation device 122: second solar panel power generation device 123: Third solar panel power generator 124: Fourth solar panel power generator 108: Environmental sensor module 100: Control module 101: Communication module 102: First hub module 103: Second hub module 104: Switch module 104A : First switch unit 104B: second switch unit 104C: third switch unit 104D: fourth switch unit 105: current sensor module 105A: first current sensor 105B: second current sensor 105C: third Current sensor 105D: fourth Flow sensor 106: Power supply module 107: Protection element AC: AC power supply 50-1: First current output monitoring device 50-2: Second current output monitoring device 50-N: Nth current output monitoring device 52: Power generation Device group L1-L4: first power line to fourth power line

Claims (7)

A current output monitoring device electrically connected to a plurality of power generation devices and a current collection device,
The current output monitoring device,
A control module;
A communication module electrically connected to the control module;
A first hub module electrically connected to the control module;
A second hub module electrically connected to the control module;
A current sensor module electrically connected to the second hub module;
A switch module electrically connected to the first hub module;
With
The switch module is electrically connected to the plurality of power generation devices and the power collection device, the switch module is disposed between the plurality of power generation devices and the power collection device, and the current sensor module is It is arranged on one side close to the current collector, used to detect a plurality of current values by the plurality of power generators,
The control module is communicably connected to a server by the communication module, receives a modulated signal from the server,
The current output monitoring device, wherein the control module adjusts the switch module on or off according to the modulation signal, thereby determining the total amount of power output that the plurality of power generation devices output to the current collection device. The current output monitoring device further includes a housing,
The current output monitor according to claim 1, wherein the control module, the communication module, the first hub module, the second hub module, the current sensor module, and the switch module are arranged in the housing. apparatus. The current output monitoring device further includes a power supply module,
The power supply module according to claim 1, wherein the power supply module is electrically connected to the control module and an AC power supply to provide driving power to the current output monitoring device, and the power supply module is an AC / DC voltage converter. Current output monitoring device. The switch module includes a first switch unit, a second switch unit, a third switch unit, and a fourth switch unit,
The current sensor module includes a first current sensor, a second current sensor, a third current sensor, and a fourth current sensor,
The plurality of power generators include a first power generator, a second power generator, a third power generator, and a fourth power generator, and the first switch unit includes the first power generator and the collector. An electrical device, the second switch unit is electrically connected to the second power generator and the current collector, and the third switch unit is connected to the third power device and The fourth switch unit is electrically connected to the current collector, the fourth switch unit is electrically connected to the fourth power generator and the current collector, and the first current sensor is connected to the first switch. A second current sensor disposed on one side of the unit proximate to the current collector, the second current sensor being disposed on one side of the second switch unit proximate to the current collector; The sensor is connected to the third switch unit. The current according to claim 1, wherein the current sensor is arranged on one side near the current collector, and the fourth current sensor is arranged on one side of the fourth switch unit near the current collector. Output monitoring device.   The current output monitoring device according to claim 4, wherein the first current sensor, the second current sensor, the third current sensor, and the fourth current sensor are Hall sensors, respectively.   The current output monitoring device according to claim 1, wherein the first hub module and the second hub module are serial communication modules, and the communication module is a wired communication module or a wireless communication module. A current monitoring system comprising four power generation devices, a current output monitoring device, and a current collection device, and communicably connected to a server,
The current output monitoring device is electrically connected to the four power generation devices,
The current output monitoring device,
A control module;
A communication module electrically connected to the control module and communicably connected to the server;
A first hub module electrically connected to the control module;
A second hub module electrically connected to the control module;
A current sensor module including four current sensors and electrically connected to the second hub module;
A switch module including four switch units electrically connected to the first hub module;
With
The power collection device is electrically connected to the current output monitoring device, and is used to supply power transmitted from the four power generation devices to a power grid system,
Each of the four switch units in the switch module is electrically connected to the four power generators, and each of the four switch units in the switch module is electrically connected to the current collector through four power lines. Connected, the four switch units in the switch module are respectively disposed between the four power generators and the current collector, and the four current sensors are respectively disposed outside the four power lines, The current monitoring system is characterized in that the four switch units of the switch module in the current output monitoring device are turned on or off according to power supply information from the server.

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