4차 산업혁명을 통해 지능형 연결 사회를 기반으로 한 스마트 시티가 형성되고 있다. 스마트 시티에서 태양 에너지를 비롯한 신재생 에너지의 사용이 증가하고 있으나, 신재생 에너지의 모니터링 및 관리의 어려움으로 인한 시스템 수요가 증가하고 있다. 또한 환경 및 물리적 요인에 대한 데이터를 수집하고 모니터링하기 위한 무선 센서네트워크 기반 IoT 기술이 접목되고 있으나, 실시간 측정을 위한 안정적인 전원 공급이 필수적인 상황이다. 이에 본 논문에서는 LoRaWan을 비롯한 IoT 기술 기반의 스마트 시티에 적용할 수 있는 효율적인 태양 에너지 기반 전력 관리 기법에 대하여 제안하였으며, 이를 기반으로 태양광 패널 시스템의 오동작 방지 및 모니터링을 수행할 수 있다. 제안한 기술을 통해 태양광 패널 시스템에서 생성된 전력을 최대로 출력하여 각 그리드에 분배할 수 있으며, Simulink 기반 시스템 모델링과 실시간 에뮬레이션을 기반으로 효율성을 입증하였다.
4차 산업혁명을 통해 지능형 연결 사회를 기반으로 한 스마트 시티가 형성되고 있다. 스마트 시티에서 태양 에너지를 비롯한 신재생 에너지의 사용이 증가하고 있으나, 신재생 에너지의 모니터링 및 관리의 어려움으로 인한 시스템 수요가 증가하고 있다. 또한 환경 및 물리적 요인에 대한 데이터를 수집하고 모니터링하기 위한 무선 센서네트워크 기반 IoT 기술이 접목되고 있으나, 실시간 측정을 위한 안정적인 전원 공급이 필수적인 상황이다. 이에 본 논문에서는 LoRaWan을 비롯한 IoT 기술 기반의 스마트 시티에 적용할 수 있는 효율적인 태양 에너지 기반 전력 관리 기법에 대하여 제안하였으며, 이를 기반으로 태양광 패널 시스템의 오동작 방지 및 모니터링을 수행할 수 있다. 제안한 기술을 통해 태양광 패널 시스템에서 생성된 전력을 최대로 출력하여 각 그리드에 분배할 수 있으며, Simulink 기반 시스템 모델링과 실시간 에뮬레이션을 기반으로 효율성을 입증하였다.
The revolution of industry 4.0 is enabling us to build an intelligent connection society called smart cities. The use of renewable energy in particular solar energy is extremely important for modern society due to the growing power demand in smart cities, but its difficult to monitor and manage in e...
The revolution of industry 4.0 is enabling us to build an intelligent connection society called smart cities. The use of renewable energy in particular solar energy is extremely important for modern society due to the growing power demand in smart cities, but its difficult to monitor and manage in each buildings since need to be deploy low energy sensors and information need to be transfer via wireless sensor network (WSN). The Internet of Things (IoT) / low-power wide-area (LPWA) is an emerging WSN technology, to collect and monitor data about environmental and physical electrical / electronics devices conditions in real time. However, providing power to IoT sensor end devices and other public electrical loads such as street lights, etc is an important challenging role because the sensor are usually battery powered and have a limited life time. In this paper, we proposes an efficient solar energy-based power management scheme for smart city based on IoT technology using LoRa wide-area network (LoRaWAN). This approach facilitates to maintain and prevent errors of solar panel based energy systems. The proposed solution maximizing output the power generated from solar panels system to distribute the power to the load and the grid. In this paper, we proved the efficiency of the proposed system with Simulink based system modeling and real-time emulation.
The revolution of industry 4.0 is enabling us to build an intelligent connection society called smart cities. The use of renewable energy in particular solar energy is extremely important for modern society due to the growing power demand in smart cities, but its difficult to monitor and manage in each buildings since need to be deploy low energy sensors and information need to be transfer via wireless sensor network (WSN). The Internet of Things (IoT) / low-power wide-area (LPWA) is an emerging WSN technology, to collect and monitor data about environmental and physical electrical / electronics devices conditions in real time. However, providing power to IoT sensor end devices and other public electrical loads such as street lights, etc is an important challenging role because the sensor are usually battery powered and have a limited life time. In this paper, we proposes an efficient solar energy-based power management scheme for smart city based on IoT technology using LoRa wide-area network (LoRaWAN). This approach facilitates to maintain and prevent errors of solar panel based energy systems. The proposed solution maximizing output the power generated from solar panels system to distribute the power to the load and the grid. In this paper, we proved the efficiency of the proposed system with Simulink based system modeling and real-time emulation.
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제안 방법
In this emulation, the proposed LoRaWAN network reliability for solar panel integrated smart city power system monitoring evaluated using packer delivery ratio (PDR) matrix. The PDR matrix is computed based on 500 packets exchanged between end-to-end node that is from the city monitoring center sink node to the each node of the solar panel integrated sensing nodes in real-time.
In this proposed system implementation, we used a wireless sensor node and gateway using DC-powered micro-controller (5V) to analyze and decode the signals received from the sensors.
The proposed solar panel monitoring system emulated using Solar Panel Model : IT-100W (21.5V), Rocket ES 15-12 (12V, 15AH), Custom DC-DC Controller with P&O MPPT controller, and Arduino Open source Hardware controller board interfaced with current, voltage, temperature, and light sensors and LoRaWAN controller as shown in [Fig. 6].
The proposed system is modeled with Battery charging system using MATLAB and performance analysed according to the MPPT controller with P&O technique as shown in [Fig. 4].
The proposed system simulation considered 12V voltage battery for charging under constant irradiation (1000W/m2) and Temperature condition (25℃). The Battery voltage charged gradually to reach 12V threshold and then stops.
The proposed system uses the low power micro-controller for data acquisition to analyze signals from sensors such as current sensors, voltage sensors, solar radiation sensors and temperature sensors. The proposed system model block diagram is shown in [Fig.
The solar energy fluctuations due to sunrise and sunset, solar energy output conversion ration in the panel direction with sunlights, and due to changing weather conditions. This paper proposes the design of PV array connected to resistive load through DC-DC boost converter with perturb and Maximum Power Point Tracking (MPPT) controller to enable maximum power output from solar panels. The proposed system simulated using MATLAB and results are discussed under constant as well as variable irradiation and temperature conditions.
성능/효과
In this paper design and simulation details of PV array connected to resistive load through DC-DC boost converter with P&O MPPT is presented and efficiency of overall system is found to be 93%.
The implementation results are discussed under constant as well as variable irradiation and varying temperature conditions. This paper found that Perturb and Observe MPPT technique is easy to implement and shows good performance under steady change in atmospheric conditions but is less suitable under fast changing atmospheric conditions. The real-time emulation confirms that the LoRaWAN network works with the average PDR of 98.
참고문헌 (10)
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