An Effective Optimal Economic Sustainable Clean Energy Solution With Reduced Carbon Capturing/Carbon Utilization/ Carbon Footprint for Grid Integrated Hybrid System
IF 3 3区 计算机科学Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
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引用次数: 0
Abstract
The integration of conventional sources with the grid has many challenges, like carbon emission, optimal cost of the system, and power quality issues. All these shortcomings create a non-sustainability in the environment, which is of great concern. In order to overcome such issues, a hybrid system is designed that is composed of various components or sources like wind energy, solar photovoltaic energy, thermal energy, and battery energy storage with the purpose of providing an environmentally friendly, economically viable, sustainable, and reliable solution. The objective is to reduce the carbon capture, carbon utilization, and carbon footprint. The carbon footprint is measured as the optimal difference between carbon capture (CC) and its utilization (CU), and carbon emission is represented as loss of carbon emission (LCE). Another objective is to reduce the optimal size of components, the distortion level, and the optimal cost in terms of loss of cost of energy (LCOE) for the various values of loss of power supply probability (LPSP). All the above objectives are accomplished by designing a nonlinear multi-objective problem. The designed nonlinear multi-objective function is based on a hybrid hysteresis fuzzy algorithm. The proposed algorithm is a combination of both fuzzy logic controllers and the hysteresis band method. The effectiveness of the proposed topology is tested on an IEEE standard 9 bus system. It is observed that a nonlinear hybrid hysteresis fuzzy algorithm provides a reliable and sustainable solution for optimal cost with a reduced effective carbon footprint and minimal distortion by maintaining the proper balance between carbon capturing and carbon utilization. The average values of LCOE,LCE, CU, and CC with the proposed method for various LPSP are found to be 0.5926 $/KWh, 70.64 g CO2/kWh, 89 g CO2/kWh, and 159 g CO2/kWh, which are the least among all methods.
传统电源与电网的集成面临许多挑战,如碳排放、系统的最佳成本和电能质量问题。所有这些缺点造成了环境的不可持续性,这引起了人们的极大关注。为了克服这些问题,设计了一种由风能、太阳能光伏、热能和电池储能等各种组件或来源组成的混合系统,目的是提供一种环境友好、经济可行、可持续和可靠的解决方案。目标是减少碳捕获、碳利用和碳足迹。碳足迹被测量为碳捕获(CC)和碳利用(CU)之间的最佳差异,碳排放被表示为碳排放损失(LCE)。另一个目标是针对不同的电源损耗概率(LPSP)值,降低组件的最佳尺寸、失真水平和能量损耗(LCOE)方面的最佳成本。所有上述目标都是通过设计一个非线性多目标问题来实现的。所设计的非线性多目标函数基于混合滞后模糊算法。所提出的算法是模糊逻辑控制器和滞后带方法的结合。所提出的拓扑结构的有效性在IEEE标准9总线系统上进行了测试。观察到,非线性混合滞后模糊算法通过保持碳捕获和碳利用之间的适当平衡,为优化成本提供了可靠和可持续的解决方案,同时减少了有效碳足迹,并将失真降至最低。对于各种LPSP,采用所提出的方法的LCOE、LCE、CU和CC的平均值分别为0.5926$/KWh、70.64 g CO2/KWh、89 g CO2/Wh和159 g CO2/kW,这是所有方法中最小的。