ArticleName |
Анализ эффективности снижения потерь водорода в трубопроводе
из различных аустенитных коррозионностойких сталей |
Abstract |
В целях снижения выбросов в атмосферу углекислого газа, образующегося в результате применения на производстве и в быту нефтепродуктов, предложено использование водорода как экологически чистого энергетического ресурса вместо стандартных видов топлива. Однако водород обладает высокой проникающей способностью, что ведет к его неизбежным диффузионным потерям через стенку трубопровода в процессе транспортировки и хранения. На основании литературных данных и математических преобразований предложена расчетная модель для оценки утечки водорода при перекачке по трубопроводу под давлением до 1,2 МПа при температуре перекачиваемой среды от 300 до 600 К. С использованием табличных литературных данных по коэффициентам проницаемости на основании расчетной модели определены возможные потери водорода при его транспортировке по трубопроводу, выполненному из разных марок аустенитных коррозионностойких сталей (304, 304L, 310, 316, 316L, 316LN, 321, 21-6-9, 21-9-9) при температурах от 300 до 600 К. По результатам расчетов установлено, что самым эффективным материалом по снижению проницаемости водорода является сталь 304L (максимальные потери ~69 л/год при температуре 600 К), а наименее эффективным — сталь 310 (903 л/год при температуре в 600 К). В остальных сталях объем потерь варьируется в диапазоне ~200–300 л/год. Анализ состава сталей показал, что снижение концентрации углерода, азота, серы и фосфора приводит к повышению ее стойкости к проникновению водорода. |
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