基于用户分类的综合能源系统低碳运行策略

doi:10.16183/j.cnki.jsjtu.2022.321

摘要/Abstract

摘要：

综合能源系统 (IES) 是实现“双碳”目标的重要手段,然而系统内部不同类型用户用能行为各异,使得IES协调优化与低碳运行难度增加.为了充分发挥用户的主观能动性,基于用户行为分析对IES的用户行为进行建模,并通过卷积神经网络将用户分为激进型和保守型.构建IES运营商决策模型,确定电热能源的供应方式,针对不用类型用户设计相应的能源套餐.基于实际数据分析上述模型和方法的有效性,验证了用户分类在IES低碳运行中的价值.

关键词: 用户分类, 用户行为, 综合能源系统, 低碳运行

Abstract:

Integrated energy system (IES) is an important means to achieve the goal of “carbon peaking and carbon neutrality”. However, different types of users in the system have different energy consumption behaviors, which makes the coordinated optimization and low-carbon operation of the integrated energy system more difficult. In order to give full play to the subjective initiative of users, the user behavior of the integrated energy system is modelled based on user behavior analysis, and users are classified into aggressive and conservative types by convolutional neural network (CNN). Then, the decision model of integrated energy system operator is constructed to determine the supply mode of electric heating energy, and the corresponding energy package is designed for different types of users. Finally, the effectiveness of the above models and methods is analyzed based on actual data, and the value of user classification in low-carbon operation of integrated energy systems is verified.

Key words: user classification, user behavior, integrated energy system (IES), low-carbon operation

中图分类号:

TM732

张春雁, 窦真兰, 白冰青, 王玲玲, 蒋传文, 熊展. 基于用户分类的综合能源系统低碳运行策略[J]. 上海交通大学学报, 2024, 58(1): 1-10.

ZHANG Chunyan, DOU Zhenlan, BAI Bingqing, WANG Lingling, JIANG Chuanwen, XIONG Zhan. Low-Carbon Operation Strategy of Integrated Energy System Based on User Classification[J]. Journal of Shanghai Jiao Tong University, 2024, 58(1): 1-10.

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层	输入	输出	超参数
卷积层	233×1	233×64	ReLU
卷积层	233×64	233×64	ReLU
最大池化层	77×64	77×64	3
Dropout层	64	64	0.2
全连接层	77×64	77×64	ReLU
全连接层	77×64	77×32	ReLU
平均池化层	77×32	32
Dropout层	32	32	0.5
Softmax输出层	32	2

用户类型	谷时电价	峰时电价	平时电价
保守型	0.60±0.05	1.00±0.05	0.70±0.05
过渡型	0.55±0.08	1.45±0.08	0.65±0.08
激进型	0.50±0.10	1.90±0.10	0.60±0.10

参数	取值	参数	取值
CHP机组容量/MW	2	电锅炉容量/MW	0.5
爬坡功率/(MW·h^-1)	1	转热效率	0.8
产电效率	0.3	燃气锅炉容量/MW	0.5
产热效率	1.2	产热效率	0.9
储能容量/(MW·h)	5	外购电碳排比例	0.8244
充电效率	0.95	燃气碳排比例	0.5704
放电效率	0.95	天然气价格/(元·m^-3)	2
最大充放电功率/MW	0.5	碳交易价格/(元·t^-1)	200
外购电容量/MW	3	热价/[元·(kW·h)^-1]	0.1

名称	数值/万元
名称	方案1	方案2	方案3
外购电成本	1.747	2.022	1.498
外购气成本	2.937	2.937	2.937
碳交易成本	0.510	0.593	0.439
用户购电成本	7.680	7.943	7.274
用户购热成本	1.358	1.358	1.358
运营商总收益	3.843	3.749	3.758

变化状态	电价/[元·(kW·h)^-1]			运营商收益/万元	用户购电成本/万元	用户购电量/ (MW·h^-1)
变化状态	谷时	峰时	平时	运营商收益/万元	用户购电成本/万元	用户购电量/ (MW·h^-1)
修订前	0.55	1.45	0.65	3.088	7.776	106.3
修订后	0.63	1.53	0.73	3.843	7.679	94.6