Analysis of Coupling Effect Between Green Hydrogen Trading Market and Electricity Market Under Carbon Trading Policy

WANG Haoran; FENG Tiantian; CUI Mingli; ZHONG Cheng

doi:10.16516/j.gedi.issn2095-8676.2023.03.004

Volume 10 Issue 3

May 2023

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Article Navigation > SOUTHERN ENERGY CONSTRUCTION > 2023 > 10(3): 32-46

WANG Haoran, FENG Tiantian, CUI Mingli, ZHONG Cheng. Analysis of Coupling Effect Between Green Hydrogen Trading Market and Electricity Market Under Carbon Trading Policy[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(3): 32-46. doi: 10.16516/j.gedi.issn2095-8676.2023.03.004

Citation:

WANG Haoran, FENG Tiantian, CUI Mingli, ZHONG Cheng. Analysis of Coupling Effect Between Green Hydrogen Trading Market and Electricity Market Under Carbon Trading Policy[J]. SOUTHERN ENERGY CONSTRUCTION, 2023, 10(3): 32-46. doi: 10.16516/j.gedi.issn2095-8676.2023.03.004

Analysis of Coupling Effect Between Green Hydrogen Trading Market and Electricity Market Under Carbon Trading Policy

doi: 10.16516/j.gedi.issn2095-8676.2023.03.004

WANG Haoran^1
,,
FENG Tiantian^{1, 2, 3
,
,},
CUI Mingli^1
,,
ZHONG Cheng^1
,

1.
School of Economics and Management, China University of Geosciences, Beijing 100083, China
2.
Key Laboratory of Carrying Capacity Assessment for Resource and Environment, Ministry of Natural Resources, Beijing 100083, China
3.
Key Laboratory of Strategic Studies, Ministry of Land and Resources, Beijing 100083, China

Received Date: 2023-02-03
Rev Recd Date: 2023-03-04

Available Online: 2023-04-04

Publish Date: 2023-05-10

Abstract

Introduction To achieve the "carbon peak and neutrality" goals, the ways for enterprise energy conservation and emission reduction need to fully explored, and the green and low-carbon policy tools should be fully exploited. Green hydrogen, as a clean energy, has become the key to social low-carbon transition thanks to its full link zero carbon emission. Carbon emission rights trading market is a key policy tool to control and reduce carbon emissions by making use of the market-oriented mechanism. Building a carbon trading center hydrogen energy industry trading mechanism to achieve the coupling of carbon trading and hydrogen energy will greatly promote the achieving of the "carbon peak and neutrality" goals. Method Based on this, a coupling mechanism of "green hydrogen market - national carbon trading market - electricity market" was built in this paper. The "green hydrogen market - national carbon trading market - electricity market" was modeled and simulated by further utilizing the system dynamics method, and the interaction of multiple markets was studied. Result The results show that: Firstly, the coupling among the green hydrogen market, carbon trading market and electricity market can be realized through green hydrogen certification and carbon quota trading, and it is found that the coupling model is feasible through simulation. Secondly, it is found through the simulation of the basic scenario that the coupling of multiple markets can stimulate the increase of carbon price and control the increase of thermal power generation and green hydrogen production. Finally, increasing the proportion of green hydrogen certification and improving the obsolete unit elimination mechanism and carbon quota auction mechanism will help form a carbon pricing mechanism. Conclusion On the one hand, this study diversifies the green hydrogen trading models, promotes the participation of green hydrogen in carbon trading to obtain certain benefits, and reduces the hydrogen energy cost. On the other hand, it makes use of the multi-market linkage mechanism to bring into play the forced effect of carbon price and promote the reduction of the proportion of traditional fossil hydrogen production and thermal power generation.
- market coupling and synergy,
- green hydrogen,
- national carbon emission rights trading policy,
- electricity market,
- energy structure adjustment

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0. 引言

全人类为了共同保护地球生态环境和减缓温室气体排放，已有140多个经济体提出了“碳中和”承诺，并实施了一系列节能降耗的政策^[1]。中国作为发展中国家期望能够在全球问题上作出相应的贡献，因此习总书记在国际上做出来了振奋全球的“2030年前碳排放达峰，完成《巴黎协定》目标；争取2060年前碳中和”的承诺。为实现“双碳”目标，中国将构建清洁低碳安全高效的能源体系^[2]。国家发展改革委和国家能源局共同发布《氢能产业发展中长期规划（2021－2035年）》，从战略层面对我国氢能发展进行了顶层设计，以促进我国氢能产业的发展^[3]。

氢能具有资源丰富、热值高、无污染的特点，被认为是理想的清洁能源，对氢能的开发和利用是实现低碳减排目标的重要路径。绿氢以其可持续性而被认为具有良好的发展前景。绿色制氢以可再生能源为原料制取氢能，具备全过程环保、低排放、转化灵活等特点，是可再生电力的替代和补充^[4]。另外，近年来，风电和太阳能光伏发电等可再生电力增长迅猛。可再生能源发电具有极强的波动性，存在因电网短时无法消纳全部电力而导致的弃电现象，这部分弃电电量将会随着可再生能源发电装机量的快速提升而增长。即便考虑储能设备的削峰填谷作用，弃风弃光电量仍旧十分可观^[5]。因此，绿氢是未来氢能市场的发展方向，也是中国实现“双碳”目标的关键路径。绿氢应用在技术上具有可行性，但是在氢能大规模利用的经济性上存在限制。其中，电解水制氢成本较高是最大的制约。如何在保障绿氢规模化发展的前提下，降低成本成为亟须解决的问题。

为降低碳排放总量，我国实施在试点经验的基础上开展了全国碳交易机制。该政策是我国实现“双碳”目标的核心政策工具之一。2021年7月，全国碳排放权交易市场正式上线运行，标志着我国已经初步建立了碳交易市场^[6]。碳交易政策体现了谁污染谁付费的原则，将外部成本内部化，是利用市场化机制降低碳排放，也是实现“双碳”目标的重要政策工具。碳交易市场分为两级。在一级市场上，政府根据整体减排目标对交易主体分配初始碳排放权。在二级市场上，纳入交易体系的企业可以自由交易碳配额。同时，控排企业也可以购买自愿减排企业的国家核证自愿减排量（China Certified Emission Reduction，CCER），利用碳抵消机制对碳配额交易进行补充。目前，中国的碳交易市场处于运行初期，存在着交易产品较为单一和市场规模较小的问题。随着碳市场的扩容，市场对于CCER的需求将进一步升级。

基于我国政策制度的不断出台，全国碳交易市场的政策效应逐步显现，且一级市场和二级市场交易频率将提升，碳价的引导作用逐步显现。这将为不同的氢气生产工艺核定真实生产成本、收益提供重要参考依据。既然绿氢与碳交易同为实现低碳减排目标和国家低碳转型的重要路径，如果两者实现深度融合，将加快我国碳中和的步伐。

文章拟解决2个问题：（1）在全国排放权交易市场这一低碳政策衍生市场运行的背景下，如何将碳交易市场作为中间市场实现绿氢市场与电力市场之间的耦合和关联，充分挖掘减排潜力？（２）在绿氢市场、全国碳交易市场和电力市场联动的情况下，探寻发现多市场间协同优化的较优路径，既缓解氢能成本压力，又增强碳交易市场的活跃度，实现绿氢市场与碳交易市场的深度融合。

1. 文献综述

1）绿氢与电力市场耦合分析

近年来，绿氢的经济性受到氢能产业领域专家和学者们的诸多关注。制氢技术的选择决定了氢能的成本和碳排放。王彦哲等（2022）测度了不同制氢技术的成本变化趋势。研究结果表明：现阶段灰氢成本最低，绿氢成本最高。从长期角度来看，随着技术进步绿氢将成为成本最低的制氢方式，绿氢也将大规模发展^[7]。发现降低绿氢成本的因素，实现绿氢和电力市场的耦合具有必要性。刘玮等（2022）认为降低清洁氢平准化价格，需要从技术、商业模式创新等多方面协同发力，从而发挥其在能源转型及深度脱碳方面的作用^[8]。许传博等（2022）研究认为电氢耦合下风光场站氢储能配置问题可以通过商业模式进行优化^[9]。顾玖等（2022）针对氢能大规模环保供应的问题，提出了一种电-氢一体化站的构建思路。在以总运行成本最小为目标的基础上，建立电-氢一体化站的优化运行模型，该模型可以有效地提高电网削峰填谷能力以及可再生能源的消纳能力^[10]。

可再生能源发电耦合制氢技术，不仅可以降低大规模并网不稳定性，实现弃风弃光的充分利用，还可以显著提高可再生消纳率^[11]。目前电-氢耦合的运行模式主要分为3类：（1）可再生能源制氢，保证氢能的绿色生产和稳定供应^[12]；（2）发挥电解水制氢灵活响应的特性，平抑可再生能源出力波动^[13]；（3）充分利用弃风、弃光资源，提高可再生能源消纳率^[14]。由上述分析可以发现，绿氢的成本是发展的瓶颈。将清洁氢的减排量纳入全国碳市场，可以推动其降本增效，实现可持续发展。目前关于氢能与碳市场耦合的研究相对较少，有待进一步展开研究。

2）碳交易市场与电力市场耦合分析

“电-碳”耦合是将电力市场与碳排放交易市场进行关联，通过两个市场各环节交互，确保电力市场主体开展电力交易的同时履行碳交易的市场义务，使得碳市场的碳价和交易量与电力市场的电价和电源结构，相互制约和相互促进，提高碳电市场融合度^[15-16]。电力市场与碳市场协同发展，是充分挖掘两个市场减排潜力的关键，学者们也针对该问题展开了相关研究。薛贵元等（2022）为研究碳市场与电力市场的耦合关联，以江苏省为例，构建了市场多主体行为决策模型，研究发现：两个市场间虽然存在着相互制约的关系，但是碳价和电价的深度联动还未形成，通过能源结构调整、绿证交易市场的运行有助于碳市场发挥碳价的信号引导作用^[17]。冯昌森等（2021）基于区块链技术提出一种绿证交易和碳交易相结合的市场模式,将可再生能源发电企业与传统化石能源发电企业联系起来,通过设计多市场联合交易运行机制，推动能源转型，促进可再生能源的消纳和限制火力发电企业碳排放^[18]。基于中国2030碳排放强度减排目标，Feng等（2021）建立了一个政策协同模型来探讨碳交易市场与绿证交易市场间的优化关系，研究发现两个市场对电力行业碳排放存在显著的缓解作用^[19]。也有学者从电碳联动的角度研究碳市场对火力发电企业的影响^[20-21]。

综上可知，关于电力市场与碳市场融合发展的研究相对丰富。研究成果多针对碳配额交易开展，对于CCER的研究成果较少。而CCER为多元化、市场化推动全社会低成本实现碳减排目标做出了积极贡献。基于此，文章将在“电-碳”市场耦合机制研究中引入CCER，从而对两个市场的深度融合展开研究。

3）多市场耦合的研究方法

赵麟等（2022）发现，目前发电企业受到来自电力市场和碳市场竞争的双重压力，基于这一问题提出了考虑CCER机制的碳-电耦合市场中水火电协同竞价模型，并以澜沧江流域的发电站为实例验证了有效性^[22]。Song等（2021）利用系统动力学方法构建了可再生能源电力市场、超额消纳量交易市场和绿色证书市场的耦合模型。研究发现：可再生能源电力消纳保障机制不仅影响多个市场的价格和交易量，且促进了中国可再生能源发电的发展^[23]。针对售电商因分布式光伏高水平渗透而面临的困境，张晗等（2022）利用系统动力学方法分析了关键影响因素，并构建了分布式光伏市场与售电市场间的耦合模型^[24]。Wang等（2022）利用多目标优化函数研究电力市场与氢能市场耦合下氢站定价机制。研究发现：双向定价机制将电力和氢能系统连接起来，可以促进社会福利和可再生能源消费^[25]。为解决风力发电因出力不稳定而在入网时电能大量损失的问题，Liu等（2022）利用基于接入微电网的P2H（Power to Hydrogen，电力-氢能）系统，构建了考虑了氢能市场耦合电力市场的多能源交易模型，并提出了P2H系统的市场机制^[26]。万文轩等（2022）分析了碳市场和多种能源市场的耦合关系，从影响机理、交易机制和应用模式3个方面阐述了碳交易与区域综合能源系统的协同发展方式^[27]。

综上可知，市场耦合机制的研究方法较多，而对绿氢市场-碳交易市场-电力市场耦合的研究需要通过因果关系形成系统反馈。鉴于系统动力学是一门研究系统动态复杂性的学科，主要用于研究复杂系统的结构、功能与动态行为之间的相互依赖关系。该方法可以从微观角度分析各决策之间的因果关系和反馈机制，也可以预测系统未来的动态行为。因此，文章利用系统动力学（System Dynamic, SD）模型研究多市场耦合机制。

文章的主要创新点：（1）将绿氢产业引入到碳交易市场机制中，模拟绿氢市场-全国碳交易市场-电力市场间的耦合机制，设计了绿氢项目通过碳减排认证体系获取CCER从而进去全国碳交易市场获得额外的政府补贴和收益，从而促进绿氢产业的大规模发展；（2）构建绿氢市场、全国碳交易市场与电力市场的系统动力学模型。仿真模拟多市场耦合下，中国绿氢产业的发电量、碳交易价格、CCER价格等变量的动态演变趋势。

4. 结论

本研究基于绿氢市场、全国碳交易市场和电力市场的运行机理构建了多市场的耦合机制，并以此为基础利用系统动力学方法，构建了绿氢市场-全国碳交易市场-电力市场耦合模型。进而，利用Vensim软件对基准情景进行模拟，并利用多情景分析方法，考察CCER抵消比例、绿氢认证比例、落后机组淘汰率、拍卖比例和综合场景因素对耦合系统的影响。基于上述研究结果得到如下主要结论：

1）通过运行基准情景下的系统，表明文章构建的系统动力学模型可以使得绿氢市场-全国碳交易市场-电力市场耦合运行具有可行性，既有助于抑制电力行业的碳排放，也有助于可再生能源电力的消纳，并且说明探索绿氢碳减排市场化交易机制具有可行性，利用清洁氢产生的减排量纳入自愿碳减排市场交易，未来可以探索建设全国性氢交易所。而文章构建的反馈机制可以促进刺激碳价的升高，且可以控制火力发电量和绿氢生产量的上升。

2）通过分析不同CCER抵消比例和不同绿氢认证比例情景，CCER抵消比例需要合理控制，抵消比例上升虽然促进绿氢产量的增加，但是并不显著。而碳市场形成机制的核心是配额的总量控制，如果设定的抵消比例过高，相当于变相增加了总量供给，改变碳市场配额供需关系，从而影响配额的市场价格。绿氢的认证比例提升，增加了CCER供给，促使CCER价格曲线下移。绿氢通过认证获取一定的收益，能够有效提升产业化进程。因此，政府应该进一步完善氢能产业的支持政策，进一步扩大绿氢项目规模，使得更多的绿氢通过认证进入碳交易市场。

3）通过落后机组淘汰、拍卖机制引入和综合情景的仿真模拟，“电-碳”市场都将不断改革完善，碳约束会倒逼落后机组的淘汰，而拍卖机制的比例提升有助于碳价的发现，两个政策共同促进电力市场结构的优化。政府可以考虑通过这两项政策助力“双碳”目标的实现。而在综合情景中多重政策实施会拉高CCER价格但是会拉低碳配额的价格。因此，鉴于当前电力市场、氢能市场以及碳市场的发展现状，相应的节能减排政策应分阶段、分步实施，与现有政策起到衔接作用。

基于上述研究结果和主要结论，针对中国绿氢市场-全国排放权交易市场-电力市场协同发展提出如下政策建议：

1）加快将绿氢减排项目纳入CCER认证体系。碳交易市场的碳定价机制对高排放行业的约束促进了该行业对绿氢的需求。未来政府需要构建绿氢认证体系，具体明确绿氢认证CCER流程、认证机构、第三方评估机构、交易管理办法等文件。通过绿氢的认证改善绿氢产业的收益模式，改善可再生能源行业弃风弃光的现象，同时通过金融手段实现绿氢市场与电力市场的联动与融合，促进氢碳的协同发展。

2）依据历史年度碳排放量设定CCER抵消比例，并依据弃风弃光率和配额量设定绿氢认证比例。碳抵消机制实施的根本是降低高耗能企业的绩效成本。在确定抵消比例的过程中，政府需要随着碳市场的成熟，降低碳抵消比例，控制配额总量，从而增强碳约束。另外，政府需要考虑国内市场经常调整抵消比例会带来行政自由裁量权过大，以及经常调整抵消比例导致市场预期不明确，从而带来市场价格的异常波动。针对绿氢的认证需要建设规范化的流程和审核机制，促进高效的绿氢项目进入市场。

3）全国碳交易市场需要通过配额拍卖机制、控制配额总量等措施发挥碳定价机制的信号作用。目前，碳市场处于运行初期，还没有完全发挥碳市场对控排企业的倒逼机制以及信号引导的作用。未来，全国碳排放权交易市场逐步引入有偿拍卖机制，让企业真正为自己的外部环境成本买单。进一步，电力市场需要加快电价的改革机制，能够将碳成本反应到电价中，将其向终端传导。另外，火力发电企业可以通过煤电机组的改造和落后机组转为应急和调峰机组等措施，有序淘汰落后机组，保障电力系统的稳定发展。

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时间	碳排放权价格			火力发电量总供给
时间	模拟值/ (元·t⁻¹)	真实值/ (元·t⁻¹)	误差/ %	模拟值/ TWh	真实值/ TWh	误差/ %
2021.7	50.00	50.33	0.66	4808.89	4813.20	−0.09
2021.8	49.89	49.76	−0.26	4809.68	5239.70	−8.21
2021.9	48.32	45.35	−6.15	4810.47	5166.90	−6.89
均值	－	－	−1.92	－	－	−5.06

影响因素	情景	参数设定
影响因素	情景	CCER抵消比例/%	绿氢认证比例/%	落后机组淘汰率/%	碳配额拍卖比例/%
基础情景	BAU	5	2.5	0	0
CCER抵消比例	A1	7	2.5	0	0
CCER抵消比例	A2	10	2.5	0	0
绿氢认证比例	B1	5	3	0	0
绿氢认证比例	B2	5	4	0	0
落后机组淘汰率	C1	5	2.5	5	0
落后机组淘汰率	C2	5	2.5	20	0
配额拍卖比例	D1	5	2.5	0	10
配额拍卖比例	D2	5	2.5	0	20
综合情景	E1	7	3	5	10
综合情景	E2	10	4	20	20

Analysis of Coupling Effect Between Green Hydrogen Trading Market and Electricity Market Under Carbon Trading Policy

doi: 10.16516/j.gedi.issn2095-8676.2023.03.004

Abstract

References

通讯作者: 陈斌, bchen63@163.com

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