天然气半贫液脱碳工艺三元胺液配方优选

doi:10.16085/j.issn.1000-6613.2019-1090

化工进展 ›› 2020, Vol. 39 ›› Issue (3): 975-983.DOI: 10.16085/j.issn.1000-6613.2019-1090

天然气半贫液脱碳工艺三元胺液配方优选

陈杰¹(),张媛媛²,花亦怀¹,唐建峰²(),郭昊³,田汝峰³,曾庆军³

^1.中海石油气电集团有限责任公司技术研发中心，北京 100027
^2.中国石油大学（华东）储运与建筑工程学院，山东青岛 266580
^3.中海石油（中国）有限公司湛江分公司，广东湛江 524057

收稿日期:2019-07-09 出版日期:2020-03-05 发布日期:2020-04-03
通讯作者: 唐建峰
作者简介:陈杰（1973—），教授级高级工程师，研究方向为天然气液化技术与关键设备开发。E-mail：chenjielng@126.com。
基金资助:
天然气预处理用大型塔器研制（工信部联装［2014］495）;国家高技术研究发展计划(2013AA09A216)

Screening of ternary amine solution for natural gas semi-lean liquid decarburization process

Jie CHEN¹(),Yuanyuan ZHANG²,Yihuai HUA¹,Jianfeng TANG²(),Hao GUO³,Rufeng TIAN³,Qingjun ZENG³

^1.CNOOC Gas & Power Group Research & Development Center, Beijing 100027, China
^2.College of Pipeline and Civil Engineering, China University of Petroleum (East China), Qingdao 266580, Shandong, China
^3.CNOOC China Limited, Zhanjiang Branch, Zhanjiang 524057, Guangdong, China

Received:2019-07-09 Online:2020-03-05 Published:2020-04-03
Contact: Jianfeng TANG

摘要/Abstract

摘要：

为实现天然气脱碳工厂降本增效目标，基于某工厂PZ活化MDEA半贫液工艺，在现有设备能力下进一步提升胺液性能，进行三元复配胺液配方筛选以替代原有吸收剂。本文针对单一胺液的贫液、半贫液及富液分别进行实验，确定合适的主体胺液及添加剂，将胺液进行三元复配后通过实验探究三元复配胺液的吸收及再生性能，旨在寻找吸收容量大、吸收速率快、解吸率高、循环溶解度高、再生能耗低综合性能优的胺液配方。通过研究发现，单一胺液中AMP、DETA及PZ吸收性能较优，TEA再生能耗最低，解吸率最高；对于三元复配胺液而言，当MDEA/DEEA为主体胺液时，两种胺液配方贫液状态下的吸收速率和吸收负荷均较高，MDEA/TEA双主体胺液的最终解吸率高于MDEA/DEEA双主体胺液，TEA的加入显著提高了胺液的解吸率；筛选得到的三元高效胺液配方18%MDEA+18%TEA+4%PZ的半贫液循环溶解度高于原PZ活化MDEA配方，再生能耗较低，可代替PZ活化MDEA胺液应用于天然气半贫液脱碳工艺。

关键词: 半贫液工艺, 单一胺液, 三元复配胺液, 吸收性能, 再生能耗

Abstract:

In order to achieve the goal of reducing cost and increasing efficiency in natural gas decarburization plant, this paper, based on thesemi-lean MDEAsemi-lean liquid process activated by PZ in a plant, further improves the performance of amine liquid under the existing equipment capacity, and selects the formula of ternary complex amine liquid to replace the original absorbent. The appropriate subject amine liquid and additive were selected by experiment of barren solution with single amine liquid, half barren solution and rich liquid, respectively. Then, the absorption and regeneration performance of the ternary blends with amine liquid were studied to determine the, look for large capacity of absorption, quick absorption rates, high desorption rate, circulating high solubility and low energy consumption of regeneration of optimum comprehensive properties for determination of amine liquid formula. It was found that AMP, DETA and PZ had better absorption performance in single amine solution, and TEA has the lowest energy consumption and highest desorption rate. For ternary complex amine solution, when MDEA/DEEA was the main amine solution, the absorption rate and absorption load of the two amine solutions were both higher in the state of poor solution. The final desorption rate of MDEA/TEA dual-main amine solution was higher than that of MDEA/DEEA dual-main amine solution. The addition of TEA significantly improved the desorption rate of amine solution. The recycling solubility ofsemi-lean solution of the selected ternary high-efficiency amine solution 18%MDEA+18%TEA+4%PZ formula was higher than that of the original PZ activated MDEA formula, and the renewable energy consumption was lower, which can replace PZ activated MDEA amine solution for the decarburization process of natural gassemi-lean solution.

Key words: semi-lean process, monoamine solution, ternary complex amine solution, absorption property, renewable energy consumption

中图分类号:

TE644

陈杰,张媛媛,花亦怀,唐建峰,郭昊,田汝峰,曾庆军. 天然气半贫液脱碳工艺三元胺液配方优选[J]. 化工进展, 2020, 39(3): 975-983.

Jie CHEN,Yuanyuan ZHANG,Yihuai HUA,Jianfeng TANG,Hao GUO,Rufeng TIAN,Qingjun ZENG. Screening of ternary amine solution for natural gas semi-lean liquid decarburization process[J]. Chemical Industry and Engineering Progress, 2020, 39(3): 975-983.

图/表 18

图1 半贫液工艺流程图

图2 单一胺液贫液吸收速率对比图

图3 单一胺液贫液吸收负荷对比图

表1 各单一胺液饱和容量

单一胺液	饱和容量/mLCO₂·(3mL胺液)^-1
MDEA	112
DEEA	130
TEA	80
PZ	119
AMP	142
DETA	155

图4 单一胺液半贫液吸收速率对比图

图5 单一胺液半贫液吸收负荷对比图

图6 单一胺液解吸曲线对比图

图7 单一胺液解吸率对比图

图8 不同单一胺液CO2相对再生能耗对比图

表2 双主体三元胺液配方

配方	质量分数/%
MDEA+TEA+PZ	18+18+4
MDEA+DEEA+PZ	18+18+4
MDEA+TEA+AMP	18+18+4
MDEA+DEEA+AMP	18+18+4

图9 三元复配贫液吸收负荷对比图

图10 三元复配贫液吸收速率对比图

图11 三元复配半贫液吸收负荷对比图

图12 三元复配半贫液吸收速率对比图

图13 三元复配富液解吸曲线对比图

图14 三元复配富液解吸率对比

图15 富液CO2相对再生能耗

表3 较优胺液配方循环溶解度

胺液配方	质量分数/%	半贫液循环溶解度 /mL·(3mL胺液)^-1
MDEA+TEA+PZ	18+18+4	25
MDEA+PZ	37+3	22

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天然气半贫液脱碳工艺三元胺液配方优选

Screening of ternary amine solution for natural gas semi-lean liquid decarburization process

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