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集中供热系统低碳清洁化演进技术研究 版权信息
- ISBN:9787121448201
- 条形码:9787121448201 ; 978-7-121-44820-1
- 装帧:平塑
- 册数:暂无
- 重量:暂无
- 所属分类:>
集中供热系统低碳清洁化演进技术研究 本书特色
本书基于既有供热系统的技术现状和“双碳”目标的要求,提出了逐步实现多能互补低温区域供热系统终极目标的技术路线、技术措施、优化设计方法。
集中供热系统低碳清洁化演进技术研究 内容简介
本书聚焦既有城市供热系统低碳清洁化演进技术研究,包括:室内供热系统分阶段降低运行参数,城市可再生能源多能互补低温区域供热系统及其热源;基于既有供热系统的低碳清洁化能源站设备的优化配置;基于既有区域能源系统的低碳清洁化热源的优化配置;建立了热电协同调度的优化模型等,为区域供热系统热电一体化调度提供了算法。本书为第四代区域供热系统奠定了基础。 本书可供城市供热、供电、可再生能源等专业的工程技术人员使用,也可作为高等学校师生的参考资料。
集中供热系统低碳清洁化演进技术研究 目录
第1 章 绪论 ······································································.001
1.1 背景和意义 ····························································.002
1.1.1 碳达峰与碳中和 ··············································.002
1.1.2 风电发展与弃风 ··············································.002
1.1.3 清洁供热目标 ·················································.005
1.2 供热技术的现状与问题 ·············································.007
1.2.1 现行规范 ·······················································.007
1.2.2 高温热媒与低品位可再生能源 ···························.008
1.2.3 热力站间接连接 ··············································.010
1.2.4 要求热泵出水温度高 ········································.010
1.2.5 无补偿冷安装难以真正实现 ······························.011
1.3 推进低碳清洁供热技术的途径 ····································.011
1.4 研究现状与分析 ······················································.014
第2 章 既有散热器低温运行存在的问题及解决方法 ··················.017
2.1 低温运行存在的问题 ················································.022
2.1.1 散热器面积的变化 ···········································.022
2.1.2 室内温度的变化 ··············································.028
2.2 低温散热器的应用 ···················································.033
2.3 室内混合供热系统的应用 ··········································.035
2.3.1 散热器和地板辐射串联系统 ······························.035
2.3.2 散热器和毛细管串联系统 ·································.037
2.3.3 散热器和谷电协调供热·····································.037
第3 章 既有供热系统转化为多能互补低温区域供热系统 ············.039
3.1 单管区域供热系统 ···················································.042
3.1.1 单管系统的循环泵 ···········································.047
3.1.2 热量分配 ·······················································.048
3.1.3 用户供回水温度 ··············································.048
3.1.4 单管系统的主要特点 ········································.049
3.2 双管区域供热系统 ···················································.050
3.3 三管区域供热系统 ···················································.052
第4 章 多能互补低温区域供热系统热源 ·································.055
4.1 基本热源 ·······························································.056
4.1.1 区域性热力站 ·················································.056
4.1.2 低温核供热堆 ·················································.056
4.1.3 垃圾焚烧锅炉 ·················································.059
4.1.4 热电厂 ··························································.059
4.2 集中调峰热源 ·························································.060
4.2.1 生物质锅炉 ····················································.060
4.2.2 中深层地热能 ·················································.061
4.3 能源站 ··································································.062
4.3.1 布置在单管系统的双向能源站 ···························.063
4.3.2 布置在双管系统的双向能源站 ···························.067
4.3.3 布置在三管系统的双向能源站 ···························.071
第5 章 既有供热系统建设能源站设备的优化方法 ·····················.075
5.1 新建能源站系统配置 ················································.076
5.2 清洁供热系统的运行优化 ··········································.077
5.2.1 运行优化的目标函数 ········································.077
5.2.2 运行优化的约束条件 ········································.079
5.2.3 决策变量 ·······················································.082
5.3 能源站设备容量优化 ················································.082
5.3.1 设备容量优化目标函数·····································.082
5.3.2 设备容量优化的约束条件 ·································.084
5.3.3 设备容量优化的计算流程 ·································.085
5.4 能源站设备容量优化案例及讨论 ·································.085
5.4.1 综合计算条件 ·················································.086
5.4.2 遗传算法和模式搜索及其解 ························.088
5.4.3 热源各机组运行工况的对比分析 ························.090
5.4.4 分时电价和余热量的影响 ·································.096
第6 章 既有能源系统配置低碳清洁热源的优化方法 ··················.099
6.1 低碳清洁热源 ·························································.100
6.2 低碳清洁热源装机容量的优化模型 ······························.101
6.2.1 设备容量优化目标函数与约束条件 ·····················.101
6.2.2 区域能源系统机组的能耗计算 ···························.104
6.2.3 区域能源系统总能耗费的优化目标函数与约束条件 .107
6.2.4 优化计算流程 ·················································.111
6.3 低碳清洁热源设备优化配置案例 ·································.111
6.3.1 风电场风资源及风电功率 ·································.111
6.3.2 区域能源系统的电源和热源、电负荷和热负荷 ······.113
6.3.3 既有区域能源系统设备的供电、供热及系统弃风 ···.115
6.3.4 配置低碳清洁热源的区域能源系统的仿真计算 ····
集中供热系统低碳清洁化演进技术研究 作者简介
王晋达,博士,2019年12月毕业于哈尔滨工业大学市政与环境工程学院供热、供燃气、通风及空调工程专业。就职于河北工业大学能源与环境工程学院从教。从事集中供热系统机理仿真建模与优化控制,风电消纳和低碳清洁可再生能源多能互补供热系统的研究。主持河北省教育厅青年基金项目融合管网拓扑约束可再生能源站的优化配置与协同调控机理研究;参与了黑龙江省科技厅, 黑龙江省自然科学基金(重点项目)严寒地区智能集中供热系统的理论与关键技术研究;参与了国家科技部, 国家科技支撑计划课题消纳风电的热-电联合优化规划及运行控制技术研究。 部分研究成果目前已获得较好应用。以作者和通讯作者身份发表 10余篇相关领域学术论文。拥有相关领域发明专利6项。
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