Construction Scheme for the System Coupling Coal Chemical Industry with Green Electricity and Green Hydrogen

SHI Zhipeng; SHI Xiangjian; CAI Dan; FENG Kangkang; LOU Qinghui

doi:10.16516/j.gedi.issn2095-8676.2023.03.016

Volume 10 Issue 3

May 2023

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Article Navigation > SOUTHERN ENERGY CONSTRUCTION > 2023 > 10(3): 143-149

SHI Zhipeng, SHI Xiangjian, CAI Dan, FENG Kangkang, LOU Qinghui. Construction Scheme for the System Coupling Coal Chemical Industry with Green Electricity and Green Hydrogen[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(3): 143-149. doi: 10.16516/j.gedi.issn2095-8676.2023.03.016

Citation:

SHI Zhipeng, SHI Xiangjian, CAI Dan, FENG Kangkang, LOU Qinghui. Construction Scheme for the System Coupling Coal Chemical Industry with Green Electricity and Green Hydrogen[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(3): 143-149. doi: 10.16516/j.gedi.issn2095-8676.2023.03.016

Construction Scheme for the System Coupling Coal Chemical Industry with Green Electricity and Green Hydrogen

doi: 10.16516/j.gedi.issn2095-8676.2023.03.016

Nanjing Nanrui Jibao Electric Co., Ltd., Nanjing 210000, Jiangsu, China

Received Date: 2023-04-10
Rev Recd Date: 2023-04-21

Available Online: 2023-05-17

Publish Date: 2023-05-10

Abstract

Introduction With the advancement of the "carbon peak and neutrality" process, it is imperative to reduce carbon and emissions in the coal chemical industry. The coal chemical process uses a large amount of hydrogen, which mainly converted from fossil fuels, resulting in residual carbon emissions. If green electricity and green hydrogen are coupled with coal chemical construction, it will not only promote energy conservation and emission reduction in the coal chemical industry, but also facilitate the large-scale application of green electricity and green hydrogen. Method In this paper, taking the typical coal chemical process of coal to ethylene glycol as an example, the system construction scheme for coupling green electricity and green hydrogen to produce ethylene glycol from coal was elaborated in detail. Result Analysis shows that the introduction of green hydrogen has improved the carbon utilization rate of coal to ethylene glycol, from 21.1% in the conventional process to 40.5% in coupled system, while the carbon emission intensity per ton of finished ethylene glycol has decreased from 2.58 t CO₂ to 0.93 t CO₂. At the same time, integrated construction can reduce the cost of secondary system construction and operation and maintenance. Conclusion The coupling construction of green electricity, green hydrogen, and coal chemical industry is technically feasible with large development potential, but there are still many challenges to overcome.
- green electricity,
- green hydrogen,
- coal chemical industry,
- coupling construction,
- energy conservation and emissions reduction

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0. 引言

我国“富煤、贫油、少气”的能源禀赋促进了煤化工行业的迅速发展^[1]。但煤化工产品碳氢比低，而煤中碳氢比高，这势必造成煤利用过程中大量的碳排放^[2]。随着“双碳”进程的推进，化工行业的减碳降排势在必行。利用新能源发绿电再制绿氢提供了一个化工行业减碳思路^[3]。绿电指的是发电过程中二氧化碳排放量趋零或者完全为零，相比于传统火力发电更加绿色环保^[4]。绿电主要来源于风能、太阳能等可再生能源。得益于地势地貌的天然优势，我国太阳能、风能储量丰富，近些年来风力发电和光伏发电也发展迅速，但同时也面临着弃风弃光等新的挑战^[5-6]。

氢能是一种绿色低碳、清洁高效的二次能源，正逐步成为全球减碳降排、能源转型的重要载体^[7]。绿氢指的是以光伏、风力等可再生能源生产的绿电再电解水获取的氢气，同样整个过程中实现零碳或趋零排放^[8]。大力发展可再生能源发电制氢有望解决绿电消纳问题，减少弃风弃光现象^[9]。但当前绿氢也存在着生产效率低、存储运输难等难题^[10]。氢的存储运输难，而煤化工过程需要补入大量氢气。如果将绿氢与煤化工行业耦合起来，直接就地消纳，既解决了氢存储运输问题，又实现了煤化工过程中的补氢减碳^[11-12]。

因此文章阐述了绿电与绿氢耦合煤化工应用的一、二次系统建设方案以及技术优势，同时也指出其发展过程中还存在的一些问题与挑战，旨在为煤化工行业推动减碳降排提供一些新的思路。

1. 绿电绿氢与煤化工发展现状

1.1. 绿电绿氢

在中国，绿电主要来自于风力和光伏发电。据国家能源局统计，2022年我国风电、光伏总发电量已经达到1190 TWh，新增装机容量也突破了120 GW。但随着风光电的迅速发展扩张，绿电的消纳问题成为了新的挑战。弃风弃光指的是当风光电无法被电网消纳时人为调整风机或光伏板在低功率条件下运行所产生的弃发电量^[13]。我国整体弃风、弃光率从2016年的17.0%和10.3%分别下降至2021年的3.1%和2.0%。

近年来国内外试图通过绿氢解决绿电消纳问题，减少弃风弃光现象。绿氢的核心是电解水制氢技术，目前存在4种主流技术，分别是碱性（Alkaline，ALK）水电解、质子交换膜（Proton Exchange Membrane，PEM）水电解、阴离子交换膜（Anion Exchange Membrane，AEM）水电解和固体氧化物（Solid Oxide Electrolyzer Cells，SOEC）水电解。其中AEM和SOEC技术仍处于实验室、示范起步阶段，离成熟商业化、产业化的路还很长^[14-15]。而ALK和PEM技术在过去十几年内已经充分发展并产业化。因此在接下来一段时间内，ALK及PEM制氢仍将是电解水制氢的主流工艺路线。目前，国内已有新能源发电制绿氢项目示范落地。中石化新疆库车绿氢项目是全球在建的最大光伏绿氢项目，这是国内首次规模化利用光伏发电直接制氢的项目，贯通光伏发电、绿电输送、绿电制氢、氢气储存输送和绿氢炼化五大部分，建成之后能实现年产2万t绿氢。此外，还有很多省市也在积极开展氢能试点示范，例如国网安徽六安制氢示范项目、河北建投张家口沽源风电制氢示范项目等等。

1.2. 煤化工

中国现代煤化工产业发展迅速，一批批新型煤化工项目不断建成投产。“十三五”末，我国煤制油、煤制烯烃、煤制乙二醇的年产量分别达到8.23 Mt/a、16.72 Mt/a和5.97 Mt/a，并仍在持续增长中^[16]。煤中氢碳比约为4∶5，而煤化工的下游产品例如烯烃、油、天然气中的氢碳比分别为2∶1，2∶1和4∶1^[17]。煤化工过程中原料和产品氢碳比的不匹配导致整个工艺中存在碳冗余，尤其当产业达到一定规模时，氢碳比不匹配带来的高煤消耗以及高碳排放不可小觑。外源性补氢是调整煤化工工艺中氢碳比的重要手段，例如煤制氢或者天然气重整制氢。但采用煤或者天然气等制得的氢气属于灰氢，仍有很高的碳排放，并不能从源头上解决煤利用过程中的低碳^[18]。

总的来说，煤化工行业的氢气需求量大，但目前基本全部使用的是灰氢^[19]。使用绿氢不仅可以替代灰氢为煤化工过程中补充高纯氢气，还可以促进煤化工行业节能减排。但国内目前还没有绿电绿氢与煤化工耦合建设的成功工业化案例，还处于研发和试点示范阶段。

4. 问题与挑战

4.1. 绿电与绿氢行业

从绿电与绿氢行业看，由于风力发电和光伏发电天然具有波动性、间歇性等特点。实现风电光电大规模稳定制氢仍面临很多技术难题和挑战。目前，还没有完全意义上绿电直接制氢项目，大多是风电光电上网后再利用网电电解水制氢。此外，虽然绿氢的碳排放明显小于化石燃料转化成的灰氢，但目前绿氢的生产成本却是灰氢的4～6倍。

4.2. 煤化工行业

从煤化工行业看：（1）绿氢价格相比于灰氢完全没有价格优势，企业考虑经济效益放弃灰氢而去使用绿氢的意愿不强。绿电制氢的波动性也有悖于煤化工工艺流程稳定用氢需求；（2）煤化工行业初期投资巨大，改造起来难度高，而大规模绿电制氢耦合煤化工目前还没有完善的标准规范以及相对成熟的经验可以借鉴。此外，虽然绿氢替代水煤气变换制氢会简化现有煤化工工艺流程，降低整个生产过程煤耗、能耗、排放，但目前也没有系统性的研究及可行性分析。

5. 结论

1）绿电与绿氢耦合煤化工系统可减少灰氢的使用，提高原煤到化工成品的碳转换率。这既有利于煤化工行业节能减排，同时也能为绿电与绿氢的发展提供巨大应用场景。具有技术可行性，发展前景广阔。

2）绿电与绿氢耦合煤化工系统可以建设二次一体化平台，采用统一开放的软、硬件平台及通信标准，通过数据共享及融合，提升各系统互联互通能力，实现跨专业控制、保护及各类高级应用，提高煤化工企业运行管理的水平及效率。

3）目前绿电与绿氢耦合煤化工还面临着绿氢成本高、不稳定，缺少成熟经验等挑战。建议国家有关部门、新能源企业、煤化工企业等需要联合攻关，合作解决绿电与绿氢耦合煤化工发展中的关键性技术，探索一种技术和经济可行的绿电与绿氢耦合煤化工的发展路径。

Reference (21)

Construction Scheme for the System Coupling Coal Chemical Industry with Green Electricity and Green Hydrogen

doi: 10.16516/j.gedi.issn2095-8676.2023.03.016