间接供热一级泵系统压差控制方案研究
摘要:以北京某建筑综合体集中供热项目为例,定量分析了间接供热系统中一级泵在不同压差控制方案下的全年逐时运行能耗。结果表明,相比常规的始端定压差和末端定压差运行,基于末端阀门开度检测的一级泵变压差运行可以显著降低供热输配能耗,提高换热站一次侧电动调节阀的调节精度,具有较好的经济性。
关键词:集中供热间接供热一级泵定压差变压差输配能耗
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参考文献[1] 胡建平,常亮.供热一次网集中量调节技术经济探讨[J].区域供热,2015(6):92- 96.
[2] 吴雪飞.基于差分进化算法的供热管网阻抗辨识及变压差优化控制方法研究[D].青岛:青岛理工大学,2022:11- 15.
[3] 郭蕙心.基于变压差控制的水泵变频调控研究[D].天津:天津大学,2019:8- 16.
[4] 马桂飞.集中供热系统变压差优化控制方法研究[D].大连:大连理工大学,2013:9- 16.
[5] 文成功,吴家瑾.热水供暖一次管网变压差调控探讨[J].暖通空调,2007,37(10):65- 67.
[6] 周俊,李楠,冯松松,等.基于末端负荷监测的变压差控制方法研究[J].暖通空调,2023,53(6):135- 141.
[7] 潘毅群,吴刚,Volker Hartkopf.建筑全能耗分析软件EnergyPlus及其应用[J].暖通空调,2004,34(9):2- 7.
[8] 冯晶琛,丁云飞,吴会军.EnergyPlus能耗模拟软件及其应用工具[J].建筑节能,2012,40(1):64- 67,80.
[9] U.S.Department of Energy's (DOE) Building Technologies Office (BTO).EnergyPlus[DB/OL].[2023-05-22].https://www.energyplus.net.
[10] U.S.Department of Energy's (DOE) Building Technologies Office (BTO).Weather data[DB/OL].[2023-05-22].https://www.energyplus.net/weather.
[11] Grundfos Pumps Ltd..Grundfos product center_sizing and selection of pumps and pump solutions_Grundfos[DB/OL].[2023-05-22].https://product-selection.grundfos.com/front-page.html.
[12] 潘云钢.我国暖通空调自动控制系统的现状与发展[J].暖通空调,2012,42(11):1- 8.
[13] AHONEN T,TAMMINEN J,AHOLA J,et al.Estimation of pump operational state with model-based methods[J].Energy conversion and management,2010,51:1319- 1325.
[14] 曹荣光,潘云钢,徐稳龙,等.厦门新机场分布式区域供热输配二级泵系统定压差方案比选[J].暖通空调,2021,51(9):67- 77.
[15] KAYA D,YAGMUR E A,YIGIT S,et al.Energy efficiency in pumps[J].Energy conversion and management,2008,49(6):1662- 1673.
[16] 曹荣光,由世俊,张欢,等.变流量水系统调速水泵运行测试分析[J].暖通空调,2011,41(8):121- 124.
[17] 伍小亭,王砚,王蓬,等.广州大学城区域供热3#制冷站的设计思考[J].暖通空调,2010,40(6):23- 27.
[18] 赵天怡.空调冷冻水系统变压差设定值优化控制方法[D].哈尔滨:哈尔滨工业大学,2009:5- 10.
[19] 邓祺,刘新民.不同节能控制技术在空调热水系统中的碰撞[J].暖通空调,2015,45(4):13- 21.
[20] MA Z J,WANG S W.Energy efficient control of variable speed pumps in complex building central air-conditioning systems[J].Energy and buildings,2009,41(2):197- 205.
[21] 赵天怡,张吉礼,马良栋,等.并联变频水泵在线优化控制方法[J].暖通空调,2011,41(4):96- 101.
[22] 曹荣光.供暖空调水系统定压差控制模式定量分析[J].暖通空调,2018,48(8):9- 16.
[23] 曹荣光.区域供热多级泵系统能效研究[D].天津:天津大学,2011:35.
[2] 吴雪飞.基于差分进化算法的供热管网阻抗辨识及变压差优化控制方法研究[D].青岛:青岛理工大学,2022:11- 15.
[3] 郭蕙心.基于变压差控制的水泵变频调控研究[D].天津:天津大学,2019:8- 16.
[4] 马桂飞.集中供热系统变压差优化控制方法研究[D].大连:大连理工大学,2013:9- 16.
[5] 文成功,吴家瑾.热水供暖一次管网变压差调控探讨[J].暖通空调,2007,37(10):65- 67.
[6] 周俊,李楠,冯松松,等.基于末端负荷监测的变压差控制方法研究[J].暖通空调,2023,53(6):135- 141.
[7] 潘毅群,吴刚,Volker Hartkopf.建筑全能耗分析软件EnergyPlus及其应用[J].暖通空调,2004,34(9):2- 7.
[8] 冯晶琛,丁云飞,吴会军.EnergyPlus能耗模拟软件及其应用工具[J].建筑节能,2012,40(1):64- 67,80.
[9] U.S.Department of Energy's (DOE) Building Technologies Office (BTO).EnergyPlus[DB/OL].[2023-05-22].https://www.energyplus.net.
[10] U.S.Department of Energy's (DOE) Building Technologies Office (BTO).Weather data[DB/OL].[2023-05-22].https://www.energyplus.net/weather.
[11] Grundfos Pumps Ltd..Grundfos product center_sizing and selection of pumps and pump solutions_Grundfos[DB/OL].[2023-05-22].https://product-selection.grundfos.com/front-page.html.
[12] 潘云钢.我国暖通空调自动控制系统的现状与发展[J].暖通空调,2012,42(11):1- 8.
[13] AHONEN T,TAMMINEN J,AHOLA J,et al.Estimation of pump operational state with model-based methods[J].Energy conversion and management,2010,51:1319- 1325.
[14] 曹荣光,潘云钢,徐稳龙,等.厦门新机场分布式区域供热输配二级泵系统定压差方案比选[J].暖通空调,2021,51(9):67- 77.
[15] KAYA D,YAGMUR E A,YIGIT S,et al.Energy efficiency in pumps[J].Energy conversion and management,2008,49(6):1662- 1673.
[16] 曹荣光,由世俊,张欢,等.变流量水系统调速水泵运行测试分析[J].暖通空调,2011,41(8):121- 124.
[17] 伍小亭,王砚,王蓬,等.广州大学城区域供热3#制冷站的设计思考[J].暖通空调,2010,40(6):23- 27.
[18] 赵天怡.空调冷冻水系统变压差设定值优化控制方法[D].哈尔滨:哈尔滨工业大学,2009:5- 10.
[19] 邓祺,刘新民.不同节能控制技术在空调热水系统中的碰撞[J].暖通空调,2015,45(4):13- 21.
[20] MA Z J,WANG S W.Energy efficient control of variable speed pumps in complex building central air-conditioning systems[J].Energy and buildings,2009,41(2):197- 205.
[21] 赵天怡,张吉礼,马良栋,等.并联变频水泵在线优化控制方法[J].暖通空调,2011,41(4):96- 101.
[22] 曹荣光.供暖空调水系统定压差控制模式定量分析[J].暖通空调,2018,48(8):9- 16.
[23] 曹荣光.区域供热多级泵系统能效研究[D].天津:天津大学,2011:35.
Study on pressure difference control schemes for indirect heating primary water pumping distribution systems
Abstract: Taking the central heating project of a building complex in Beijing as an example, this paper quantitatively analyses the annual hourly operating energy consumption of the indirect heating primary water pumping distribution system under different pressure difference control schemes. The results show that compared with the conventional constant pressure difference at the near and end, the variable pressure difference operation of the primary water pump based on end valve opening detection can significantly reduce the energy consumption of heating transmission and distribution, improve the adjustment accuracy of the electric control valve on the primary side of the heat exchange station, and have good economy.
Keywords: central heating; indirect heating; primary water pump; constant pressure difference; variable pressure difference; transmission and distribution energy consumption;
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