基于工业余热与可再生能源耦合的赤峰市低碳供热研究
摘要:以赤峰市大温差供热工程实践为例,介绍了赤峰市低碳供热方案的设计理念和实施步骤。从赤峰市供热热源紧缺,城区周边电厂乏汽余热、工业余热和弃风电力转化热量潜力估算,降低一次网回水温度必要性,大温差供热推进和分阶段实施过程,各阶段热平衡等5个方面进行了详细说明。根据规划,至2035年赤峰市中心城区供热热量来源于非供暖季储存弃风电力转化热量和工业余热,以及供暖季工业余热和燃煤调峰电厂热量,单位供热面积的二氧化碳排放强度是现状的1/30。
关键词:低碳供热零碳热源工业余热弃风电力大温差供热跨季节储热回水温度
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[2] 董磊,王萌,夏建军,等.严寒地区集中供热小区现状测试研究[J].暖通空调,2014,44(2):77- 83,122.
[3] 甘益明,王昱乾,黄畅,等.“双碳”目标下供热机组深度调峰与深度节能技术发展路径[J].热力发电,2022,51(8):1- 8.
[4] 方豪,王春林,林波荣.我国钢铁余热清洁供暖现状和产能调整下的余热潜力预测[J].建筑节能,2019,47(6):106- 111.
[5] 付林,李永红.利用电厂余热的大温差长输供热模式[J].华电技术,2020,42(11):56- 61.
[6] 吴彦廷,尹顺永,付林,等.“热电协同”提升热电联产灵活性[J].区域供热,2018(1):32- 38.
[7] 张俊月,郭放,黄海龙,等.工业余热跨季节储热系统优化及经济性分析[J].太阳能学报,2020,41(1):47- 53.
[8] 李永红,张世钢,付林.不同热网回水温度对电厂余热回收供热的经济性影响[J].区域供热,2015(4):5- 9,22.
[9] 方豪,夏建军,宿颖波,等.回收低品位工业余热用于城镇集中供热:赤峰案例介绍[J].区域供热,2013(3):28- 35.
[10] 江亿,谢晓云,朱超逸.实现楼宇式热力站的立式吸收式换热器技术[J].区域供热,2015(4):38- 44.
[11] 张世钢,付林,李永红,等.吸收式换热过程及设备[J].暖通空调,2015,45(9):85- 90.
[12] 方豪,夏建军,江亿.热源定价机制应用案例介绍[J].区域供热,2015(4):59- 61.
Low carbon heating in Chifeng based on coupling of industrial waste heat and renewable energy
Abstract: Taking the practice of Chifeng's large temperature difference heating project as an example, this paper presents the design concept and implementation steps of low carbon heating scheme in Chifeng. From the shortage of heat sources, the estimation of the potential of steam waste heat, industrial waste heat and wind power conversion, the necessity of reducing the temperature of primary network return water, the promotion of large temperature difference heating and the implementation process in stages, and the heat balance at each stage in Chifeng are described in detail. According to the plan, by 2035, the heating heat in the central urban area of Chifeng comes from the conversion heat of wind curtailment power stored in non-heating season and industrial waste heat, as well as the heat of industrial waste heat and coal-fired peaking power plant in heating season. The carbon dioxide emission intensity per unit heating area is 1/30 of the current situation.
Keywords: low carbon heating; zero carbon heat source; industrial waste heat; wind curtailment power; large temperature difference heating; seasonal heat storage; return water temperature;
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