考虑农村用能多样性的碳路径分析及综合能量管理策略研究

doi:10.3969/j.issn.2097-0706.2026.03.006

摘要/Abstract

摘要：

积极发挥农户自建生物质反应器、光电设备、光热设备的供能支撑作用，引导构筑面向个体用户、具备孤岛自主运行能力的低碳微型综合能源系统，可以削减用户对集中式供能的路径依赖性。针对农村绿能生产设备多样化、用能行为复杂化造成的碳排放路径模糊问题，提出一种内嵌主从物理知识的多层卷积神经网络（PI-CNN），通过主、从知识库间深度交互，发掘用户用能行为与碳排放间的映射关系，实现碳排放路径的精准追踪。根据PI-CNN网络学习结果，对碳排放路径、辐射状配电网潮流、用户热电分时价格分配适宜权重，设计计及运行综合碳排放、电网全局潮流均匀度、用户用能总收益的能量管理策略评估模型，量化用能方案质量。考虑到集中式不均匀多目标优化问题求解困难，结合自适应梯度算法解数学问题，拟定兼顾经济性、低碳性、鲁棒性的综合能量管理策略。以华南某村落为例开展仿真分析，验证PI-CNN的可行性和能量管理策略的优越性。

关键词: 农村住宅, 低碳运行, 卷积神经网络, 综合能源系统, 自适应梯度算法, 碳排放路径

Abstract:

The proactive utilization of self-built biomass reactors by rural residents， photovoltaic equipment， and solar thermal equipment in energy supply can facilitate the development of low-carbon micro-integrated energy systems with islanded autonomous operation capabilities for individual users， thereby reducing their reliance on centralized power supply. To address the ambiguity in carbon emission pathways resulting from the diversified green energy production equipment and complex energy consumption behaviors in rural areas， a multi-layer physics-informed convolutional neural Network （PI-CNN） embedded with primary and secondary knowledge was proposed. Through deep interaction between primary and secondary knowledge bases， the model uncovered the mapping relationships between user energy consumption behaviors and carbon emissions， enabling precise tracking of carbon emission paths. Based on the learning outcomes of the PI-CNN network， appropriate weights were assigned to carbon emission pathways， radial distribution network power flows， and time-of-use heat and electricity pricing. An energy management strategy evaluation model was then designed by considering operational integrated carbon emissions， global power flow uniformity of the grid， and total benefits of user energy consumption， to quantify the quality of energy solutions. To address the challenges in solving centralized heterogeneous multi-objective optimization problems， an integrated energy management strategy was developed to balance economic efficiency， low-carbon performance， and robustness by combining adaptive gradient algorithms for mathematical problem solving. Simulation analysis conducted in a village in southern China verified the feasibility of PI-CNN and demonstrated the advantages of the proposed energy management strategy.

Key words: rural house, low-carbon operation, convolutional neural network, integrated energy system, adaptive gradient algorithm, carbon emission pathway

中图分类号:

TK 019

张杨, 陶生虎, 刘琪. 考虑农村用能多样性的碳路径分析及综合能量管理策略研究[J]. 综合智慧能源, 2026, 48(3): 56-64.

ZHANG Yang, TAO Shenghu, LIU Qi. Carbon pathway analysis and integrated energy management strategy considering rural energy consumption diversity[J]. Integrated Intelligent Energy, 2026, 48(3): 56-64.

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方法	E_total权重	C_total权重	U_ij权重
试凑法	0.11	0.37	0.52
BP神经网络	0.17	0.34	0.49
常规CNN	0.16	0.42	0.44
深度学习网络	0.15	0.40	0.45
遗传算法	0.14	0.38	0.48
PI-CNN	0.21	0.42	0.37

方法	E_total/kg	C_total/万元	U_ij(标幺值)
试凑法	10.60	100.21	0.992
BP神经网络	9.84	103.65	0.997
常规CNN	9.71	101.72	0.996
深度学习网络	9.80	102.50	0.995
遗传算法	9.75	101.50	0.994
PN-CNN	9.66	101.84	0.996