KR20200079138A - Real time power saving system - Google Patents

Abstract

The present invention relates to an optimized demand response system through real-time power data collection. More particularly, the present invention relates to an optimized demand response system through real-time power data collection which can save electric energy by allowing a device to operate itself in response to power collection data according to the power data analysis result and can perform energy consumption optimized for an environment of the building.

Description

Optimized demand response system through real-time power data collection {Real time power saving system}

The present invention relates to an optimized demand response system through real-time power data collection, and more specifically, according to the power data analysis result, the device can save electric energy by operating in response to the power collection data. The present invention relates to an optimized demand response system through real-time power data collection in which energy consumption optimized for the environment can be performed.

Currently, smart device products are a single item-oriented market that controls individual power consumption devices. And in the case of software, it is limited to the monitoring level, such as turning the device on or off or manually operating the set temperature.

In addition, energy-saving devices related to outlets, lights, and air conditioners have limitations in that they cannot perform energy saving operations on their own, such as operating only on a server command.

Therefore, it is necessary to develop a system that can operate itself and perform an energy saving function.

KR10-1035127 (Registration No.) 2011.05.09.

An object of the present invention is to provide an optimized demand response system through real-time power data collection that can save energy by operating a power consumption device in response to power data collected by itself in accordance with power data analysis results.

In addition, an object of the present invention is to provide an optimized demand response system through real-time power data collection, in which energy consumption optimized for a building environment can be performed using data collected in real time from an internal environment sensing device.

The present invention, a power consumption device including any one or more of a lighting device, an outlet device, a temperature control device, an air conditioning device; It communicates with the power consumption device by wire or wirelessly, receives power consumption measurement values in real time from the power consumption device, accumulates and analyzes power consumption based on the measurement values, generates an electric power reduction instruction, and transmits it to the power consumption device The control device includes; but, the power consumption device adjusts power consumption to correspond to a power reduction instruction transmitted from the control device.

In addition, the present invention is provided in the power consumption device or in the space where the power consumption device is installed to measure the power consumed by the power consumption device, or the temperature, humidity, and fine dust concentration in the space where the power consumption device is installed, Includes an internal environment detection device for measuring one or more of the illuminance or detecting the presence or absence of a person, wherein the control device communicates with the internal environment detection device by wire or wirelessly, and is transmitted from the internal environment detection device. A power reduction instruction is generated based on environmental data and real-time power consumption measurement values transmitted from the power consumption device.

The present invention has an effect of saving energy by operating the power consumption device in response to power collection data according to the power data analysis result.

In addition, the present invention has an effect that energy consumption optimized for the environment of a building can be performed using data collected in real time from an internal environment sensing device.

1 is a conceptual diagram of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
2 is an exemplary diagram illustrating the operation of interlocking the occupancy sensor of the optimized demand response system through real-time power data collection according to an embodiment of the present invention.
3 is an IoT module block diagram of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
4 is a block diagram of a temperature controller of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
5 is a block diagram of an occupancy sensor of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
6 is a block diagram of an outlet device of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
7 is an LED lighting block diagram of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.
8 is an energy meter block diagram of an optimized demand response system through real-time power data collection according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention, as shown in Figures 1 to 8, the lighting device, an outlet device, a temperature control device, and a power consumption device including any one or more of an air conditioning device, and the power consumption device is wired or wirelessly communicated, A control device that receives power consumption measurement values from the power consumption device in real time, accumulates and analyzes power consumption based on the measured values, generates a power reduction instruction, and transmits the power consumption device to the power consumption device. An internal environment detection device provided in a space to measure the power consumed by a power consumption device, or to measure one or more of temperature, humidity, fine dust concentration, and illuminance in a space where a power consumption device is installed, or to detect the presence or absence of a person Including.

The power consuming device is a device that consumes power such as a lighting device, an outlet device, a temperature control device, and an air conditioning device, and includes indoor lighting, power outlets, air conditioners, heaters, heat exchangers, air cleaners, refrigerators, TVs, and computers. do.

The power consumption device is built in to measure the current value consumed by a built-in current sensor, and is connected to the control device through a wired or wireless network. The power consuming device may be configured to enable centralized communication to the control device, but preferably, communication between each power consuming device is made so that mutual power consumption can be supplemented and corrected immediately.

Each power consuming device has a structure that is divided into IoT modules and main hardware types for each device, and a common embedded software module library applied to each power consuming device is applied.

Each power consuming device is configured to enable automatic network binding, so that when the power consuming device is additionally installed in the field, it is configured to automatically bind to the mesh network generated by the Zigbee coordinator without any complicated process. In addition, automatic encryption and macro binding functions between the control device and the power consumption device are supported.

When the power consumption device is a temperature controller, the operating software for the temperature controller is ported to the IoT module, and a complex context awareness algorithm for automatic energy saving determination is implemented. In addition, an air wave function in the form of a software inverter is configured to maximize energy savings when operating the air conditioner. When the power consumption device is an air conditioner or an air conditioner, it is configured to enable automatic or manual learning of a remote control signal. In addition, when the power consumption device is a temperature controller, an air conditioner, or an air conditioning device, reference hardware for a main board circuit and an expansion board into which an IoT module ported with embedded operation software is inserted is presented, and the reference hardware of the present invention is applied and extended. Standard design guides can be presented so that new hardware can be designed.

The power consumption device is based on a Zigbee wireless communication, and a heuristic-based mesh network search algorithm is supported to secure communication quality according to the network conditions of the device. The power consuming device is automatically routed to the bypass search in response to the wireless network signal sensitivity.

In addition, when the power consumption device is an outlet, the IoT module is separated into a main hardware type for each device, and embedded software for situation-aware-based device operation and energy saving self-determination is mounted. In addition, it may be configured to enable real-time power usage pattern analysis, and real-time power usage pattern analysis may be performed at each power consumption device or at a control device, and reduction instruction information may be transmitted to each power consumption device. In addition, an overcurrent automatic shut-off function is basically provided. In addition, the power consumption device, which is an outlet, can be configured with hardware as a wall outlet and an outlet capable of responding to a two-hole type simultaneous mechanism, and the allowable width for overcurrent detection can be secured up to 16A.

When the power consumption device is an LED light, it is a structure that is separated into the IoT module and the main hardware type for each device, and embedded software for situation-aware-based device operation and energy saving self-determination is installed. The power consumption device, which is an LED light, is equipped with a lighting color temperature control function and can be configured to enable real-time lighting usage pattern analysis. The real-time power usage pattern analysis may be performed in each power consumption device or in a control device, so that each power consumption device The reduction instruction information may be transmitted. In addition, the power consumption device, which is an LED light, is provided with a protection circuit for coping with an inrush current of 10 A or more, and the IoT module is miniaturized and has a high degree of circuit integration so that when the IoT module is inserted in the LED light, shading by the IoT module does not occur. It is preferably configured.

Meanwhile, the IoT module for communication between each power consumption device and the control device is based on a Zigbee wireless communication, and a heuristic-based mesh network search algorithm is supported to secure communication quality according to the network conditions of the device. When the IoT module is inserted into the main board of each power consuming device, the device shape verification process is automatically performed, and the plug and play function is supported so that it can be operated immediately. In addition, simultaneous use of memory for each FRAM and EEPROM function through the embedded rich client method is supported. In addition, the IoT module has a built-in self-radio signal sensitivity measurement function, and is equipped with an extension antenna connection port for additional wireless sensitivity.

The internal environment sensing device is provided in the power consumption device or in a space where the power consumption device is installed to measure power consumed by the power consumption device, or to measure one or more of temperature, humidity, fine dust concentration, and illuminance in the space where the power consumption device is installed. It serves to measure or detect the presence of a person.

When the internal environment sensing device measures the power consumed by the power consumption device, the internal environment sensing device may be configured as an energy meter, or may be configured to be installed on a branch line of an outlet device or a distribution panel. The energy meter is capable of measuring current by additionally attaching a CT resistance to the wire, and if the energy meter is provided on the branch line of the distribution panel, the allowable overcurrent detection width may be set to 20A, but is not limited thereto. When the energy meter is provided in the interior of the LED light, it is preferable that the compactness and circuit density are configured to prevent shading by the energy meter.

When the internal environmental sensing device is a sensor that measures temperature, humidity, fine dust concentration, and illuminance, the internal environmental sensing device transmits the measured value to the control device. At this time, the temperature, humidity, etc. may utilize a sensor attached to a temperature controller, air conditioner, or air conditioning device, but not limited thereto, a separate measurement sensor may be installed. As for the illuminance, an illuminance sensor may be installed in the room, and preferably, the illuminance may be installed for each lighting device to check how much illuminance the space in which each lighting device is installed has. Through this, when a plurality of lighting devices are arranged to perform power reduction in an installed space, it is possible to configure the lighting device to be turned on or off in a specific arrangement as well as simply adjusting the illuminance of the lighting device. When the internal environmental sensing device is a sensor for measuring the concentration of fine dust, the fine dust concentration sensor may utilize a sensor attached to an air conditioner or an air conditioner, and is not limited thereto, and a separate measurement sensor may be installed indoors.

On the other hand, when the internal environment sensing device is a presence sensor, reference hardware for a main board circuit and an expansion board into which an IoT module ported with embedded operation software is inserted is presented, and new hardware is developed by applying and extending the reference hardware of the present invention. Standard design guides can be presented so that they can be designed. The occupancy sensor is installed in a plurality of indoor spaces, and a human body detection method using a Doppler module or an infrared module or a known human body detection method may be adopted. The presence sensor may be provided with an LED indicator on the outside, for example, red may be absent, blue may be absent, and green may be detected as presence.

The control device serves to receive the measured value from the internal environment sensing device in real time and to control the driving of the power consumption device based on the measured value. For this, the power consumption device or the internal environment sensing device is wired or wireless. Are communicated.

The control device may be configured as a separate client computer, or may be integrally configured with a specific power consumption device. In summary, all means capable of generating power reduction indication information and transmitting it to each power consuming device based on the measured value of the internal environment sensing device become the control device of the present invention. Therefore, in the present invention, it should be noted that the term'device' is not limited to one station, but a system capable of'control' is collectively used as a term of the control device.

The control device generates power reduction indication information based on the information of the power consumption of the power consumption device and the environmental measurement values measured from the internal environment detection device, and transmits the power reduction indication information to each power consumption device. Therefore, it is possible to realize the demand response automatically without manual control of the manager. In addition, if the power consumption of the power consumption device exceeds the set value from the past cumulative average value by using the accumulated data, the possibility of overcurrent is alerted, or the power is automatically cut off and the administrator is notified, thereby actively responding to electrical safety accidents. It becomes possible. If a fire or electrical safety accident occurs, it can be configured to automatically guide the evacuation route by appropriately controlling the lighting device.

In addition, the present invention provides an open API as an open platform structure to easily interwork with other systems, and is configured to implement various application services externally. In addition, it is possible to remotely access and monitor from the outside using a web or app, and it is possible to present a criterion for reducing power consumption or to quickly check when a failure occurs.

In addition, for real-time power data, it can provide effective services for various comparative analysis and prediction such as power load, group, device status, and regional situation. Web application that only supported simple monitoring through PHP and DHTML By switching to REACT library based and improving based on responsive web UI, you can get the effect of improving development quality and productivity.

In addition, by providing a web-based chart component linkage service and reporting service optimized for real-time power data analysis, the linkage function for real-time power data analysis is inserted into the chart library responsible for the visual effect of the power data analysis part, which is the core of the energy management system. Can be.

The present invention made of the above-described configuration has an effect of saving energy by operating the power consumption device in response to power collection data according to the result of power data analysis.

In addition, the present invention has an effect that energy consumption optimized for the environment of a building can be performed using data collected in real time from an internal environment sensing device.

Claims (2)

A power consumption device including any one or more of a lighting device, an outlet device, a temperature control device, and an air conditioning device;
It communicates with the power consumption device by wire or wirelessly, receives power consumption measurement values in real time from the power consumption device, accumulates and analyzes power consumption based on the measurement values, generates a power reduction instruction, and transmits it to the power consumption device Control device;
Including,
The power consumption device is an optimized demand response system through real-time power data collection to adjust power consumption to correspond to a power reduction instruction transmitted from the control device.
According to claim 1,
It is provided inside the power consuming device or in a space where the power consuming device is installed to measure power consumed by the power consuming device, or to measure one or more of temperature, humidity, fine dust concentration, and illuminance in the space where the power consuming device is installed. Or an internal environment sensing device that detects the presence or absence of a person;
It includes,
The control device communicates with the internal environment sensing device by wire or wirelessly, and generates a power reduction instruction based on internal environment data transmitted from the internal environment sensing device and real-time power consumption measurement value transmitted from the power consumption device. Optimized demand response system through power data collection.

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