Summary of Global Energy Storage Market Tracking (Q3 2024)

China market: Pumped Hydro Storage share falls below 50% for the first time. Non-hydro Storage accumulative installations surpass 50GW for the first time.

According to CNESA DataLink's Global Energy Storage Database, as of the end of September 2024, the cumulative installed capacity of operational energy storage projects in China reached 111.49 GW. This includes pumped hydro storage, molten salt thermal storage, and other non-hydro storage technologies, marking a year-on-year increase of 48% and a 29% rise since the end of 2023. The share of pumped hydro storage in the total installed capacity fell below 50% for the first time. Among these, the cumulative installed capacity of non-hydro energy storage surpassed 50 GW for the first time, reaching 55.18 GW/125.18 GWh. Power capacity grew by 119% year-on-year, while energy capacity surged by 244% year-on-year. 

Fig 1: Cumulative installed capacity distribution of total energy storage projects in China (as of the end of Sep 2024), unit: MW%

In the first three quarters of 2024, newly operational non-hydro energy storage installations reached 20.67 GW/50.72 GWh, representing year-on-year growth of 69% in power capacity and 99% in energy capacity. In Q3 alone, newly installed capacity amounted to 6.79 GW/16.89 GWh, showing year-on-year increases of 62% and 99%, but quarter-on-quarter declines of 29% and 26%, respectively. 

Fig 2: Cumulative Installed Capacity of Operational Non-hydro Energy Storage Projects in China (as of Sep 2024)

China EPC bidding update of 2024 Q3: Bidding reaches record high, energy storage system bid prices hit historic lows

In the first three quarters of 2024, the bidding volumes for battery systems, energy storage systems, and EPC projects all exceeded the same period of 2023 in terms of energy capacity. Among these, EPC bidding reached its highest-ever quarterly volume in Q3, approaching 50 GWh. Large-scale projects, particularly those exceeding 500 MWh and even GWh-level, saw a significant increase in EPC bidding announcements. State Power Investment Corporation (SPIC) led with a bidding volume exceeding 7 GWh.

Fig 3: Distribution of Typical Bidding Types (Jan–Sep 2024) (Unit: GWh)

Fig 4: Top 10 EPC Bidders by Scale (Jan–Sep 2024) (Unit: GWh)

Energy storage system bid prices hit a record low

In the first three quarters, the average bid price for domestic non-hydro energy storage systems (0.5C lithium iron phosphate systems) was 622.90 RMB/kWh, a year-on-year decline of 50%. While bid prices remained relatively stable in the first half of the year, they reached a historic low of 578.11 RMB/kWh in Q3, particularly in September. This marks a 42% year-on-year decrease, a 4% quarter-on-quarter decline, and a 26% drop compared to early 2024. For the first time, prices fell below 500 RMB/kWh. 

This downward trend was partly driven by falling upstream lithium carbonate prices, which fluctuated around 100k–110k RMB/ton in the first half of the year. Since late June, prices declined steadily, dropping below 80,000 RMB/ton in September due to inventory reductions and weakened downstream demand.

Note: 0.5C lithium iron phosphate battery energy storage system, excluding user side application; The average bid price is the arithmetic average of the bid price of each project in the statistical period. 

Fig 5: Trends in Energy Storage System and EPC Bid Prices (Jan 2023–Sep 2024) (Unit: RMB/kWh)

United States: the new installed capacity is 6.5GW+ in the first three quarters. Q3 installation declines after record Q2

As of September 2024, the U.S. added 27.1 GW of cumulative operational battery storage, a year-on-year growth of 70% and a 34% increase from the end of 2023. Newly operational installations (≥1 MW) in the first three quarters reached 6,807.4 MW, a 57% year-on-year increase. After achieving a record high in Q2, Q3 installations fell to 2,578.8 MW, a 14% quarter-on-quarter decline but a 0.4% year-on-year increase. Regionally, California continued to lead with over 40% of new installations, followed by Texas and Arizona. Independent storage projects dominated, accounting for two-thirds of the total.  

United Kingdom: Q3 Marks Installation Peak for 2024

As of September 2024, the U.K. reached 4.3 GW/5.8 GWh in cumulative operational battery storage, with an average duration of 1.33 hours. In the first three quarters, 19 new battery projects totaling 579 MW were added, a year-on-year decline of 52%. After two quarters of declining installations, Q3 achieved a new 2024 high at 259 MW, up 90% quarter-on-quarter but down 38% year-on-year. New projects in Q3 ranged from 10–50 MW with durations between 1–2.4 hours. 

Additionally, 4.3 GW of battery capacity is expected to sign capacity market agreements by October 2024. By the end of Q3, 1.4 GW of battery capacity for the 2024/25 market had yet to connect, with an estimated 280–780 MW to come online in Q4. 

Germany: Slowing Growth in Monthly Installations

In the first three quarters of 2024, Germany added 2,672.5 MW/3,965.3 MWh of battery storage, a slight year-on-year decline of 3%/5%. Q3 installations reached 716.9 MW/1,138.7 MWh, down 28%/25% year-on-year and 23%/16% quarter-on-quarter. 

Residential storage accounted for 88% of new installations in both Q3 and year-to-date figures (by energy capacity). By September 2024, Germany's cumulative battery storage installations totaled 10.3 GW/15.9 GWh, with residential systems making up 85% of the total. Over 1.5 million residential systems have been installed, with over 400,000 added in the first three quarters of 2024.

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Summary of Global Energy Storage Market Tracking (Q2 2023)

Pumped hydro accounted for less than 70% for the first time, and the cumulative installed capacity of new energy storage(i.e. non-pumped hydro ES) exceeded 20GW.

According to incomplete statistics from CNESA DataLink Global Energy Storage Database, by the end of June 2023, the cumulative installed capacity of electrical energy storage projects commissioned in China was 70.2GW, with a year-on-year increase of 44%. The cumulative installed capacity of pumped hydro dropped to 69.1% by the end of June this year, which was below 70% for the first time after it was below 80% for the first time at the end of last year. The cumulative installed capacity of new energy storage projects is 21.1GW/44.6GWh, and the power and energy scale have increased by more than 225% year-on-year.

Figure 1: Cumulative installed capacity (MW%) of electric energy storage projects commissioned in China (as of the end of June 2023)

Figure 2: Cumulative installed capacity of new energy storage projects commissioned in China (as of the end of June 2023)

In the first half of 2023, China's new energy storage continued to develop at a high speed, with 850 projects (including planning, under construction and commissioned projects), more than twice that of the same period last year. The newly commissioned scale is 8.0GW/16.7GWh, higher than the new scale level last year (7.3GW/15.9GWh). The newly-added projects were mainly put into operation in June, and the capacity reached 3.95GW/8.31GWh, accounting for 50% of the total increased capacity of operarting projects in the first half of the year. It is expected that it will continue to maintain a rapid growth in the second half of the year, and the installed capacity will increase by 15-20GW in 2023.

Figure 3: Installed capacity of new energy storage projects newly commissioned in China (2023.H1)

In the first half of the year, the capacity of domestic energy storage system which completed procurement process was nearly 34GWh, and the average bid price decreased by 14% compared with last year.

In the first half of 2023, a total of 466 procurement information released by 276 enterprises were followed. The bidding volume of energy storage systems (including energy storage batteries and battery systems) was 33.8GWh, and the average bid price of two-hour energy storage systems (excluding users) was ¥1.33/Wh, which was 14% lower than the average price level of last year and 25% lower than that of January this year.

Figure 4: Capacity of main types of energy storage bidding in the first half of 2023

Figure 5: Trend of average bid price in energy storage system and EPC (2023.H1, unit: CNY/kWh)

About Global Energy Storage Market Tracking Report

Global Energy Storage Market Tracking Report is a quarterly publication of market data and dynamic information written by the research department of China Energy Storage Alliance (CNESA).

About CNESA Data Link Global Energy Storage Database

Independently built by CNESA, CNESA DataLink Global Energy Storage Database is an intelligent data service platform for energy storage industry, providing important data support for government agencies, power generation groups, power grid companies, energy storage enterprises, industry organizations, investment and financing institutions, etc. to understand the market status, judge future trends, assist decision-making, and make plans.

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10MW for the First Phase! The World's First Salt Cavern Compressed Air Energy Storage Power Station Officially Enters Commercial Operation

On September 23, Shandong Feicheng Salt Cave Advanced Compressed Air Energy Storage Peak-shaving Power Station made significant progress. The first phase of the 10MW demonstration power station passed the grid connection acceptance and was officially connected to the grid for power generation. This marked the world’s first salt cave advanced compressed air power station. The energy storage power station has entered a state of formal commercial operation. The Feicheng Salt Cave Compressed Air Energy Storage Power Station technology was developed by the Institute of Engineering Thermophysics, Chinese Academy of Sciences. This technology has the advantages of large scale, low cost, long life, and environmental friendliness. It is one of the most promising large-scale energy storage technologies.

该项目利用肥城地下丰富的盐穴资源。当电网负荷较低时,空气经压缩机压缩后进入盐穴储存。当电网负荷达到峰值时,释放高压空气驱动膨胀机做功,带动发电机发电。实现电力系统调峰、调相、旋转备用、应急响应、黑启动等功能。该项目正式并网发电。这是我国盐穴压缩空气储能领域的一个重要里程碑,将我国压缩空气储能技术提升到一个新的水平,具有划时代的意义。

项目实施和试运行过程中,得到了泰安市委市政府、肥城市委市政府、肥城市经济开发区、泰安能源局、国网泰安的大力支持供电公司和肥城供电公司为项目的正式商业运营提供了条件。强有力的保证。

该项目负责人表示,肥城压缩空气储能国家示范电站正式投运,将有力推动电力系统运行管理发生重大变革,有力支持能源革命,提高发电比重可再生能源发电,助力“碳中和”目标的实现,带动相关产业发展,服务肥城经济发展。

Guangxi’s Largest Peak-Valley Electricity Price Gap is 0.79 yuan/kWh, Encouraging Industrial and Commercial Users to Deploy Energy Storage System

9月7日广西发改委发布《关于完善广西谷分时电价公众机制征求意见的公告》,鼓励企业用户降低峰值用电——提高谷地利用、配置能源、能源能源综合利用。电力,通过改变用电时间段来降低用电成本。

文件提出在电价持平的基础上高度聚合最大50%,形成峰谷电价,在峰谷电价上浮20%,形成峰谷电价。据北极星网恢复,广西政策峰谷差价达到0.7932元/千瓦时,形成同时,广西单日电价十二峰分别对应谷两个谷,有用户仰峰侧支撑项目的发展。

此外,文件还了低谷蓄热电锅和冷库电动汽车充电桩、农业冷链物流等的电价政策,从而实现了高峰设备期。

广东、广东、浙江感应发出分时电价政策,包括:

广东的峰谷比由现在的1.65:1:0.5调整为1.7:1:0.38。高峰电价在上述峰谷分时电价的高峰电价基础上调25%。峰谷间最大峰谷差价达到1.1735元/千瓦时,峰谷价也为0.8877元/kWh。将于2021年10月1日开始实施。

浙江峰谷峰谷差价与谷电价超过0.82元/电价电价时。其中,大工业电价与电价工商业电价存在差异。低大工业电价电价1、7、8月份。将于2021年10月15日日起实施。

Shandong Revises the Operating Rules of the Power Auxiliary Service Market

9月3日,山东省能源整合办公室引用发布了《山东省电力服务辅助市场规则运行》(2021年修订)(征求稿)。经验从6元/兆瓦改为8元/兆瓦,再降6元/兆瓦,重上调至8元/兆,增加了用户付费调峰辅助服务和虚拟设备紧急辅助服务,还有最小化用户调整时间不小于2小时最小响应能力,不小于1兆瓦。

文件备份,辅助设备作为个人参与的电力服务,充电功率可以不小于5MW,连续充电时间不小于2小时,即恢复容量不小于5MW/10MWh。

调峰:参与有偿调峰交易的设备,包括独立能源设备和集中式新站配套设施。设备提前提供次日充电能力、可调用能源(调用时长电池)11小时)、交易价格。可以声明3个生命周期。

当火电机组调峰低速运行通知时,参与充电调调峰应用服务为400元/瓦时。充电宝示范项目有偿调交易时,不收费,200/200/瓦时通知。于最大时间出力的50% ,电力调度机构将优先使用启动启动应用项目。

AGC调频:试运行,AGC调频辅助服务监控价暂定执行8元/MW,下限0元/MW。的,提前调用综合调节性能指标的或功能。

The National Energy Board Solicits Opinions on the new version of the "Two Rules", and the New Type of Energy Storage is Listed as a Market Entity

On August 31, the Comprehensive Department of the National Energy Board issued an announcement on the public solicitation of opinions on the "Administrative Regulations on Grid-connected Entity and Operation (Draft for Comments)" and "Administrative Measures for Auxiliary Services of the Power System (Draft for Comments)". The "Regulations" and "Measures" will be implemented from the date of promulgation, with a validity period of 5 years.

The "Administrative Regulations on Grid-Connected Operation of Grid-connected Entities" apply to the thermal power, hydropower, nuclear power, wind power, photovoltaic power generation, pumped storage, new energy storage and other grid-connected entities that are directly dispatched by provincial-level and above power dispatching agencies, and can respond to provincial-level and adjustable loads ordered by the above power dispatching agencies (including those aggregated through aggregators, virtual power plants, etc.), self-supplied power plants, and conditionally participating grid-connected entities that can be indirectly dispatched by municipal-level and below power dispatching agencies (Collectively referred to as grid-connected entities).

The “Regulations” point out that the grid-connected entities on the power generation side should work with grid companies in accordance with the principles of equality and mutual benefit, consensus and ensuring the safe operation of the power system, with reference to the "Grid-connected Dispatching Agreement (Model Text)" and "Power Purchase and Sale Contract (Model Text) 》Sign the grid-connected dispatch agreement and the electricity purchase and sale contract in time, and must not connect to the grid without agreement. Other grid-connected entities shall sign relevant agreements and contracts in accordance with relevant regulations.

When a grid accident or network security incident occurs, the grid-connected entities on the power generation side shall not be connected to the grid until the cause has been identified, and other grid-connected entities shall not participate in grid regulation before the cause has been identified.

The "Administrative Measures for Power System Auxiliary Services" apply to the provision, invocation, assessment, compensation, settlement and supervision and management of power auxiliary services within the dispatching jurisdiction of power dispatch agencies at the provincial level and above. The main power auxiliary service providers include thermal power, hydropower, and nuclear power. Grid-connected entities (collectively referred to as “grid-connected entities,” such as wind power, photovoltaic power generation, pumped storage, new energy storage, etc., as well as user-adjustable loads that can respond to dispatch instructions (including adjustable loads aggregated through aggregators, virtual power plants, etc.) "). The grid-connected resources and qualified self-provided power plants dispatched by electric power dispatching agencies at the municipal level and below may be included in the local electric power auxiliary service management implementation rules or market transaction rules.

The "Measures" pointed out that when the agencies dispatched by the National Energy Board formulate the implementation rules for the management of auxiliary power services, in principle, they mainly stipulate the relevant mechanisms for the types of auxiliary power services obtained through voluntary provision and fixed compensation; in formulating the auxiliary power service market When trading rules, it mainly stipulates the relevant mechanisms of primary frequency modulation, secondary frequency modulation, peak shaving, standby, moment of inertia, climbing and other electric auxiliary service varieties obtained through marketization.

Power users participate in the ancillary service are involving in a sharing mechanism. According to the principle of “ provides, benefits, and bears” principle, gradually establish an ancillary service sharing and sharing mechanism in which power users participate, and differentiate the sharing of different types of power users according to local conditions. Power users can participate in power auxiliary services through independent participation and entrusted-agent participation.

Cross-province and cross-regional power transmission supporting power supply units, "point-to-grid" units, "point-to-point" units, and "network-to-grid" units shall be included in the management of auxiliary power services in accordance with these measures, and be connected to the receiving end or the transmitting end according to actual operation conditions. The power grid participates in auxiliary power services, in principle, it does not repeatedly participate in the transmission and management of auxiliary power services at both ends.

The new version of the "Two Rules" expands the new main body of grid-connected operation management and auxiliary services, adds new types of power auxiliary services, improves the new mechanism for sharing and sharing auxiliary services, reduces the increasing auxiliary service costs of power system operation, and improves more flexibility. The market-based price competition mechanism further reduces system operating costs. The new version of the document lays a new foundation for the construction of my country's auxiliary service market, improves the deficiencies of the original mechanism under the new situation, conforms to the new changes and new needs of my country's energy structure transformation, and matches the reform and construction of my country's power market, which will be effective stimulate the vitality of the market and promote the continuous emergence of new business models.

The new version of the "Two Rules" covers all key elements such as new grid-connected entities, new types of auxiliary services, technology access, participation mechanisms, demand determination, invocation mechanisms, assessment mechanisms, compensation mechanisms, and apportionment mechanisms, indicating that the country will give full play to The determination of the market mechanism, only through the formation of transaction prices through the market mechanism, reducing the cost of system auxiliary services, and optimizing system operation efficiency, can the decisive role of the market in resource allocation be better played, and new energy storage, virtual power plants, etc. can be better played The value and role of new technologies.

After the release of the new "Two Rules", it will be able to better guide the construction and implementation of the local auxiliary service market. In this process, we believe that energy storage as a new technology and new entity will fully participate in the construction and competition of the market Play its role and value. In this process, the China Energy Storage Alliance is preparing to establish an auxiliary service committee, which will provide think tank support for all parties in the industry, and jointly promote energy storage to participate in related work in the auxiliary service market.

The First Domestic Commercial Power Station with Compressed Air Energy Storage Connected to the Grid

On August 4, Shandong Tai'an Feicheng 10MW compressed air energy storage power station successfully delivered power at one time, marking the smooth realization of grid connection of the first domestic compressed air energy storage commercial power station. The Feicheng 10 MW compressed air energy storage power station equipment was developed by the Chinese Academy of Sciences. Taking full advantage of the natural advantages of good airtightness and high stability of underground salt caverns in the bordering yard of Feicheng, Tai'an, the air is compressed into the salt cavern cavity when the grid load is low, and the exhaust gas is used to drive the generator to generate electricity when the grid load peaks, so as to realize auxiliary grid reduction. The smooth implementation of the project will play a demonstrative and leading role in enhancing system regulation capabilities, ensuring the safe and stable operation of the power grid, and improving new energy load support capabilities.

China 's First Regional Frequency Regulation Auxiliary Service Market Operates

With the approval of the Southern Regulatory Bureau of the National Energy Administration, the country's first regional ancillary service market with FR services as trading product-the Southern China Regional FR Auxiliary Service Market will be officially put into operation on July 1. Since it started in Guangdong in September 2018, the southern regional FR auxiliary service market has expanded to four provinces: Guangdong, Guangxi, Yunnan, and Hainan. The market has "distributed orders" (frequency regulation mileage instructions) more than 48 million times, and market compensation costs amounted to RMB2.82 billion, allowing more participants to earn the dividends of market-oriented reforms.

Industry insiders have vividly compared the southern regional FR auxiliary service market to an online car-hailing platform. Power dispatch agencies are similar to online car-hailing platform operators, which issue system adjustment requirements (frequency regulation mileage instructions) based on the real-time load, operating conditions, and frequency fluctuations of the power system, similar to the “order dispatching” of online car-hailing platforms; Each power generation unit is similar to a "driver" who grabs orders, and submits an adjustment application to the dispatching agency based on its own adjustment performance and market quotation; after the order is successfully grabbed (confirmed as the winning unit), it is responsible for the system frequency adjustment according to the frequency control instruction issued by the dispatching agency, and receives the order perform the tasks required by the order. "Drivers" who take orders quickly and run orders on time (fast adjustment rate) and good service attitude (accurate adjustment) can often receive more system orders (frequency regulation instructions) and get more "commissions" (compensation benefits for auxiliary services) ).

Through the market-oriented model of “delivering orders”, “grabbing orders”, “acquiring orders” and “settlement”, the four provinces of Guangdong, Guangxi, Yunnan, and Hainan competed in the frequency modulation service market in the southern region. Provide FR auxiliary services to bring substantial market compensation returns to participants. A thermal power plant in Guangdong Province that has been in operation for many years has greatly improved its output performance by installing energy storage devices. By participating in the competition of frequency regulation auxiliary services, the annual service revenue exceeds 30 million yuan, exceeding its power generation revenue.

CATL Released 58.2 billion Yuan for Fixed Increase Plan

On the evening of August 12, CATL issued a series of announcements including the "Preplan for Issuing Shares to Specific Objects". According to the announcement, CATL will determine the number of shares to be issued to specific targets based on the total amount of funds raised divided by the issue price, and at the same time, it will not exceed 10% of the company's total share capital before the issuance, that is, not more than 232,900,780 shares (including the amount), and The number of registrations approved by the China Securities Regulatory Commission shall prevail. The total amount of funds raised from the issuance of shares does not exceed RMB58.2 million (including the amount). After deducting the issuance expenses, it is planned to be used for all projects such as battery production, advanced technology research, development and application, and to supplement working capital.

This fundraising is used to expand the power and energy storage battery production capacity to 137GWh. It is expected that CATL's production capacity is expected to exceed 200/600GWh by the end of 2022, and promote the industry to accelerate into the "TWh" era. The supply chain of related lithium battery equipment and lithium battery materials is expected to benefit. In addition, CATL has increased investment in energy storage capacity and technology. As an industry leader, the company is expected to promote the development of the energy storage industry through innovation, and the progress has exceeded expectations.

National Development and Reform Commission Released Policy on Time-of-use Power Prices: Perfect Peak-valley Electricity Prices and Establish Peak Electricity Prices

On July 29, the NDRC issued the "Notice on Further Improving the Time-of-Use Electricity Price Mechanism", requesting to further improve the peak-valley electricity price mechanism, establish a peak electricity price mechanism, and improve the seasonal electricity price mechanism.

1. Improve the peak-valley price mechanism.

l  Scientifically divide peak and valley periods. All localities should consider the local power supply-demand status, system power load characteristics, the proportion of new energy installed capacity, system adjustment capabilities, and other factors. Determine the period of tight system supply with high marginal power supply costs as peak hours, and guide users to save electricity, shift and avert peak hours. Determine the period when the system supply and demand are loose and the marginal power supply cost is low as the valley period to promote the consumption of new energy and guide users to adjust the load. Where the proportion of installed renewable energy power generation capacity is high, full consideration should be given to the fluctuation of new energy power generation output and the changing characteristics of the net load curve.

l  Reasonably determine the peak-valley price. All localities should consider the local power system peak-valley ratio, the proportion of new energy installed capacity, system adjustment capacity, and other factors, and reasonably determine the peak-valley price gap. When the peak-valley ratio is expected to exceed 40% in the previous year or the current year, in principle, the electricity price difference should not be less than 4:1; and it should not be less than 3:1 in other places.

2. Establish a peak electricity price mechanism.

l   All localities should implement a peak electricity price mechanism based on actual peak and valley electricity prices conditions. The peak period should be reasonably determined according to when the highest load of the local power system is 95% or more of the electricity load in the previous two years and should be flexibly adjusted in consideration of the power supply and demand of the year, weather changes, and other factors; the peak power price rises on the basis of the peak power price in principle not less than 20%. Where cogeneration units and renewable energy have a large proportion of installed capacity, and where the contradiction between phased oversupply and demand in the power system is prominent, a deep valley electricity price mechanism can be established concerning the peak electricity price mechanism. Strengthen the coordination of peak-valley electricity price mechanism and power management policies, and fully tap the demand side adjustment capabilities.

3. Improve the seasonal electricity price mechanism.

l  Where there are obvious seasonal differences in daily power load or power supply and demand, it is necessary to further establish and improve the seasonal power price mechanism, divide the peak and valley periods by seasons, and set the seasonal peak and valley price difference reasonably; where the proportion of renewable energy such as hydropower is significant. It is necessary to comprehensively consider the complementary factors of wind and water, and further establish and improve the high and low electricity price mechanism. The high and low periods should be reasonably divided according to the characteristics of water and wind and solar output over the years, and the floating rate of electricity price should be set reasonably according to the supply and demand of the system. Encourage the northern regions to study and formulate seasonal electricity heating price policies, and promote the further reduction of clean heating electricity costs by appropriately extending the trough period and reducing the valley section of the electricity price, and effectively guaranteeing residents' demand for clean heating in winter.

Policy interpretation: Guidance comprehensively promote the development of energy storage under the ‘dual carbon’ goal

Policy interpretation.jpg

Driven by the national strategic goals of carbon peaking and carbon neutrality, energy storage, as an important technology and basic equipment supporting the new power systems, has become an inevitable trend for its large-scale development. Since April 21, 2021, the National Development and Reform Commission and the National Energy Administration have issued the ‘Guidance on Accelerating the Development of New Energy Storage (Draft for Solicitation of Comments)’(referred to as the ‘Guidance’), which has given rise to the energy storage industry and even the energy industry. The industry has given a high degree of recognition to the release of the Guidance and positive feedback. On July 23, the National Development and Reform Commission and the National Energy Administration formally issued the "Guidance" after fully soliciting suggestions from all walks of life.

China Energy Storage Alliance (CNESA) combines the research and understanding of industries and policies to briefly interpret and analyze the content of the guidelines, policies and industrial impacts:

Comparison of the ‘Guidance’ draft and official documents

Compared with the draft, the official document has not changed much, emphasizing strict adherence to the bottom line of energy storage safety, and integrating the advantages of the upstream and downstream of the industry chain through the method of "revealing the list and taking command" to promote the integrated development of industry, university, research and application, and concentrate efforts to tackle key problems in the large-scale development of the industry, promoting the diversified development of energy storage, and ensuring that energy storage becomes a strong support for the realization of the ‘dual carbon’ goal. In addition, in the improvement of the ‘new energy + energy storage’ project , adding a ‘sharing model’ has become one of the ways to implement new energy power generation projects for new energy storage, and it is clear that the ‘sharing model’ is to optimize the coordinated development of regional renewable energy and energy storage , also it is an effective way to promote the formation of a variety of energy storage business models.

The practical significance of the ‘Guidance’ to the development of the energy storage industry

1. Clarify the goal of 30GW of energy storage, and boost to achieve leapfrog development

According to the statistics of the database from China Energy Storage Alliance , the cumulative installed capacity of new electric energy storage (including electrochemical energy storage, compressed air, flywheel, super capacitor, etc.) that has been put into operation by the end of 2020 has reached 3.28GW, from 3.28GW at the end of 2020 to With 30GW in 2025, the scale of the new energy storage market will expand to 10 times the current level in the next five years, with an average annual compound growth rate of more than 55%. This total scale and growth rate, and the clarification of my country's new energy storage installed capacity targets will release positive policy signals for society and capital, guide social capital to flow into technology and industries, and boost the rapid arrival of the trillion-dollar energy storage market.

2. Emphasize planning guidance and deepen the layout of energy storage in various application fields

At present, energy storage has entered a stage of rapid development, and it is urgent for the country to coordinate all parties to issue a special plan for it. Through strengthening management and guidance, it can effectively standardize industry management, optimize industrial layout, improve the efficiency of energy storage systems, and avoid disorderly development of the industry.

In the ‘Guidance on New Energy Storage’, energy storage on the power side emphasizes the layout of system-friendly new energy power station projects, the planning and construction of large-scale clean energy bases for cross-regional transmission, and the exploration and utilization of existing plant sites and transmission and transformation facilities for decommissioned thermal power units, or wind and solar storage facilities. These tasks on the one hand meet the current demand for energy storage in the development of renewable energy, and at the same time, they are in line with the previously issued ‘Guidance on Promoting the Integration of Power Sources the Development of Multi-energy Complementarity’ and ‘Notice: Regarding the Development of Wind Power and Photovoltaic Power Generation in 2021’ . It can be said that the implementation is supported and the policies are guaranteed.

Grid side energy storage emphasizes the role of new energy storage on the flexible adjustment capability and safety and stability of the grid, improving the power supply capacity of the grid, emphasizing the emergency power supply guarantee capability of the grid, and delaying the demand for energy storage in the upgrading and transformation of power transmission and transformation. It can be said that the grid-side energy storage that has been suspended since 2019 has re-pressed the start button. At the same time, with the industry’s new understanding of grid-side energy storage and the entry of various social entities, we believe that under the guidance of policies, the grid-side energy storage Energy storage will be rejuvenated.

User side energy storage has always been the most viable application field of the energy storage industry. With the development of new infrastructure and new business formats, user-side energy storage has increasingly shown a development trend of ‘energy storage’ +. With the continuous development of the electricity market deepening, this field will be the main force in energy storage business model innovation, which will bring vitality and surprises to the development of the industry.

3. Improve the new energy storage price mechanism and promote the establishment of energy storage business models

In the "Guidance", for the first time, the establishment of a grid-side independent energy storage power station capacity price mechanism was proposed, and the study and exploration of the cost and benefit of grid alternative energy storage facilities into the recovery of transmission and distribution prices, improved the peak and valley price policy, and created greater development for the user-side energy storage space. Based on the ‘Opinions on Further Improving the Price Formation Mechanism for Pumped Storage’ and the ‘Plan on Deepening the Reform of the Price Mechanism during the 14th Five-Year’ period, the country clearly proposes the establishment of a new type of energy storage price mechanism and a new type of storage price mechanism. Energy should be formed in the form of market competition, and energy storage facilities that play the role of grid substitution will be recovered through transmission and distribution prices. New energy storage can participate in the medium and long-term, spot and ancillary service markets to obtain benefits.

4. Aiming at the points of new allocation for energy storage, and specifying the focus of subsequent policies

At present, more than 20 provinces and cities in China have issued policies for the deployment of new energy storage. After energy storage is configured, how to dispatch and operate energy storage, how to participate in the market, and how to channel costs have become the primary issues which plague new energy companies and investors. In response to the current issues in the allocation of energy storage in various provinces, the document also further clarifies the coordinated development of energy storage and new energy, through competitive configuration, project approval (filing), grid connection timing, system scheduling and operation arrangements, and ensuring utilization hours , power auxiliary service compensation and assessment, etc. are given appropriate inclination, which points out the direction for the rationalization of new energy allocation of energy storage to achieve rational cost relief. In the transitional stage of the power market reform, it is possible to further explore the feasibility of allocation of energy storage in increasing the weight of ‘green power transactions’.

 

Based on the above analysis, as the first comprehensive policy document for the energy storage industry during the ‘14th Five-Year Plan’ period, the ‘Guidance’ provided reassurance for the development of the industry. In the context of the ‘dual-carbon’  goal and energy transition, the energy storage industry’s leapfrog development is the general trend and demand. The follow-up actions will inevitably introduce a series of policies for the development of energy storage to eliminate industrial development. Faced with ‘obstacles’ one by one. At the local level, with the improvement of policies and market mechanisms, new business models will emerge. We firmly believe that China will become the world’s largest energy storage market. On this huge and diverse fertile soil, the energy storage technology from China will be fully developed and verified, and will lead the development of the global energy storage industry! After all the exploration and perseverance, China's energy storage industry will surely gain steam!

2020 Energy Storage Industry Summary: A New Stage in Large-scale Development

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Despite the effect of COVID-19 on the energy storage industry in 2020, internal industry drivers, external policies, carbon neutralization goals, and other positive factors helped maintain rapid, large-scale energy storage growth during the past year. According to statistics from the CNESA global energy storage project database, by the end of 2020, total installed energy storage project capacity in China (including physical energy storage, electrochemical energy storage, and molten salt heat storage projects) reached 33.4 GW, with 2.7GW of this comprising newly operational capacity. Newly operational electrochemical energy storage capacity also surpassed the GW level, totaling 1083.3MW/2706.1MWh (final statistics to be released in CNESA’s Energy Storage Industry White Paper 2021 in April 2021). In 2020, the year-on-year growth rate of energy storage projects was 136%, and electrochemical energy storage system costs reached a new milestone of 1500 RMB/kWh. Just as planned in the Guiding Opinions on Promoting Energy Storage Technology and Industry Development, energy storage has now stepped out of the stage of early commercialization and entered a new stage of large-scale development.

Energy storage first passed through a technical verification phase during the 12th Five-year Plan period, followed by a second phase of project demonstrations and promotion during the 13th Five-year Plan period. These phases have laid a solid foundation for the development of technologies and applications for large-scale development. In response to carbon neutralization goals, initial development plans for the energy storage industry have been set, while the strategic position of energy storage in the reformation of China’s energy structure will be further clarified during the 14th Five-year Plan period. The national government is also currently coordinating the development needs for a variety of application fields. We look forward to seeing national and local step-by-step approaches to resolving the development bottlenecks that have plagued the energy storage industry, and the creation of refined implementation plans which will help transform energy storage into a new sector for economic growth. During the 14th Five-year Plan period, energy storage technology will see further breakthroughs in performance improvement and cost reduction. With the establishment and improvement of policies and market mechanisms, the industry will achieve rapid growth, and China will have the potential to become the largest market for energy storage in the world.

Throughout 2020, energy storage industry development in China displayed five major characteristics:

1.  New Integration Trends Appeared

The integration of renewable energy with energy storage became a general trend in 2020. With increased renewable energy generation creating pressure on the power grid, local governments and power grid enterprises in 20 provinces put forward “centralized renewable energy + energy storage” development incentive policies. The policies signify that a consensus has been reached on the importance of energy storage technology to the large-scale application of renewable energy. In order for this development to continue, it will be important to create a rational plan for the deployment of energy storage, ensure the quality of project applications, and to rely on market mechanisms to determine costs and compensation. Profitability is the key to sustainable development.

"Unified" energy projects saw large-scale demonstration and promotion. The “Guiding Opinions on ‘Unified’ Energy Projects” issued by the National Development and Reform Commission and the National Energy Administration states a goal of increasing energy storage at the power side and load side to achieve a flexible and robust grid system. Since the release of the policy, numerous state-owned enterprises and provincial/municipal governments have signed "unified" demonstration project agreements. The planning and implementation of these projects will help to explore development paths and business models for energy storage under diverse scenarios and local conditions.

The value of energy storage in “cross-domain” applications has gradually emerged. The role of energy storage in the safe and stable operation of the power system is becoming increasingly prominent. Energy storage has also begun to see new applications including generation-side black start services and emergency reserve capacity for critical power users. As the construction of new infrastructure such as 5G cell towers, data centers, and EV charging stations accelerates, many regions have used price policies and financial support policies to support the construction of "integrated energy stations", which has helped to extend the “cross-domain” applications of behind-the-meter energy storage.

2.  New Rules Gradually Removed Obstacles for Energy Storage to Participate in the Market

In 2020, regional electricity market rules helped establish energy storage’s identity in the ancillary services market, swept away initial obstacles to participation in market transactions, defined basic requirements for third-parties and consumer-side resources to participate in ancillary services, and defined the basic conditions for ancillary services costs to be gradually transmitted to the power consumer. At the same time, under the existing cost-sharing mechanism, energy storage entering the market has also brought risks to the use of ancillary services funds, and local policies have been explored to combat these challenges. For example, market rules and compensation standards have been frequently adjusted in Guangdong, western Inner Mongolia, Qinghai, Shanxi, Hunan and other regional markets. As a result, it is necessary to reasonably plan how projects enter the market while ensuring energy storage can also compete fairly within the market. With the large-scale penetration of renewable energy in the grid, the idea of determining peak and off-peak electricity prices according to net load has become popular. Continued regional adjustments to the price difference between peak and off-peak power have improved the economy of behind-the-meter energy storage, and the charging and discharging strategy of energy storage projects continues to be adjusted accordingly.

3.  New Models Have Appeared, Led by "Sharing" and "Leasing"

In the past, energy storage projects widely relied on an energy management contract model. In recent years, with the introduction of relevant supporting policies and greater penetration of specialized energy storage applications, new models have begun to emerge. One such model is the shared energy storage model first launched by Qinghai Province, which has helped to increase the implementation of independent energy storage stations. Another such model is the leasing model for front-of-the-meter energy storage projects adopted by Hunan province in 2018, and the subsequent 2020 upgraded version of the leasing model which applied to energy storage paired with renewable generation and designed to split investment risks between each entity. An additional agent operator model has also emerged. This model allows third-party companies to integrate distributed energy storage systems and EV charging stations through a centralized control station to participate in grid services. The agent operator model is in part a product of the pursuit of value stacking of energy storage applications, and at the same time opens the links between power supply, power grid, and the consumer to realize the value of connecting energy storage. The continued exploration and implementation of new models will greatly promote the value of energy storage applications and the profitability of energy storage projects.

4.  Continued Breakthroughs in Technology and Continued Decline in Costs

Breakthroughs have been made in a variety of energy storage technologies. Lithium-ion battery development trends continued toward greater capacities and longer lifespans. CATL developed new LiFePO batteries which offer ultra long life capabilities, while BYD launched "blade" batteries to further improve battery cell capacities. Other energy storage technologies such as vanadium flow batteries and compressed air energy storage saw new breakthroughs in long-term energy storage capabilities. These include the vanadium flow battery stack developed by the Dalian Institute of Chemical Physics, which adopts a weldable porous ion-conductive membrane, and the successfully completed integration test of the first 100MW CAES expander by the Chinese Academy of Sciences Institute of Engineering Thermophysics. Industry attention was also devoted to the effectiveness of applications and the safety of energy storage systems, and lithium-ion battery energy storage systems saw new developments toward higher voltages.

Energy storage system costs continued to decline. Take lithium-ion battery energy storage systems as an example: as battery production scales and manufacturing processes continue to improve and energy storage systems become more highly integrated, system costs have fallen by about 75% since 2012, nearing ever closer to solar/wind parity. By 2020, the costs of energy storage systems fell to 1500 RMB/KWh, bringing storage systems closer to economic feasibility.

5.  New Forces Emerged, and Market Players Increase their Efforts to Participate

First, the capital market continued to increase investment in the energy storage industry. Many financial institutions invested in energy storage companies. Examples include Hillhouse Capital's 10.6 billion RMB investment in CATL, and the launch of IPOs by numerous energy storage companies such as Pylontech and Tianneng to raise funds to expand business. Second, new forces have sprung up, accelerating the deployment of energy storage. Traditional energy storage technology and system integrators such as CATL, Sungrow, BYD, and Narada continued to increase investments in the energy storage, while Tianjin Lishen signed an equity transfer agreement with Chengtong. At the same time, new forces in the domestic energy storage market continued to emerge, including Huawei, Envision, and Mingyang Smart Energy. In addition, solar PV companies such as Longi, Tongwei, and TrinaSolar began focus more attention on energy storage. Third, energy storage companies saw deeper integration with other industries. For example, CATL invested in a power engineering design service company, and established cooperation with the State Grid Integrated Energy Services Company. BYD partnered with Canadian Solar, Goldwind, China Resources, Chint and other domestic and international energy developers to expand the international reach of their energy storage business. The past year also saw many mineral, energy, and power companies exploring new opportunities in energy storage.

2020 was the final year of China's 13th Five-year Plan. Over the past five years, a solid foundation has been laid for energy storage in both technologies and applications. The 14th Five-year Plan is an important new window for the development of the energy storage industry, in which energy storage will become a key supporting technology for renewable energy and China’s goals of peak carbon by 2030 and carbon neutralization by 2060. As we face this new period, the question remains as to how energy storage colleagues will seize new opportunities, face changing markets, promote commercial development of energy storage, and establish a leading position in the international market.

Author: Shi Yubo Executive Vice Chairman, China Energy Research Society; Former Deputy Director, National Energy Administration

0.1 RMB per kWh: Qinghai Enacts First Renewable Energy & Energy Storage Subsidy

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Recently, the Qinghai provincial Development and Reform Commission, Department of Science and Technology, Department of Industry and Information Technology, and Energy Administration jointly issued the "Notice on the Distribution of Several Measures to Support the Development of the Energy Storage Industry (Trial)" (hereinafter referred to as the "Notice"). For “renewables + energy storage” and "hydropower + renewables + energy storage" projects which produce and store electricity sold to the provincial grid, an operating subsidy of 0.10 RMB per kilowatt hour will be provided. In addition, Qinghai’s Industry and Information Technology Department has announced that for projects with 60% or more of their batteries manufactured in Qinghai, an additional 0.05 RMB per kilowatt hour subsidy will be provided.

According to reports, the "Notice" subsidies will be available for electrochemical energy storage projects developed in 2021 and 2022, and will be settled monthly by the grid company according to the amount of electricity provided. The subsidy funds will be considered a part of the Qinghai grid’s second supervision cycle T&D price reduction reserve funds. The subsidy period is tentatively set from January 1, 2021 to December 31, 2022.

According to an expert at Kaiyuan Securities, Qinghai has always been a leading region for domestic energy storage pilot projects. The introduction of the new energy storage subsidy policy will provide valuable learning experience for other provinces who are likely to follow suit.

Alleviating the Challenge of High Cost Renewables+Storage

Since 2020, the national government has repeatedly expressed support for the development of energy storage, and many provincial governments have issued supporting documents for energy storage at the power generation side. Inner Mongolia, Xinjiang, Liaoning, Hubei, Jiangxi, Shandong, and other regions have recommended or encouraged newly constructed wind and solar projects to deploy energy storage systems. Yet industry disputes over renewables and energy storage have caused continuous challenges. One focus of controversy is who should bear the cost for energy storage. In the absence of both subsidies and a reasonable profit model, can renewables+ storage continue to develop? The Qinghai energy storage subsidy policy will provide some alleviation to the cost challenge of deploying storage with renewables.

Li Zhen, deputy secretary-general of the China Energy Storage Alliance, believes that the release of Qinghai’s energy storage subsidy policy is good for the industry. The policy makes clear that energy storage is prioritized to ensure a certain number of consumption hours, and provides clear standards for subsidy implementation. At the current transition stage in which a mature spot market has yet to be established, the subsidy policy provides reasonable compensation for energy storage services, provides an innovative mechanism for the co-development of energy storage and renewable energy, and provides a model which may inspire related policies in other regions of the country.

Huang Bibin, director of the State Grid Energy Research Institute's New Energy and Statistics Institute, stated that an increasing number of provinces are considering the system regulation challenges of connecting large-scale renewable energy to the grid, and have begun to require renewable energy projects to be equipped with energy storage in order to meet grid-connection requirements and improve the regulation capability of the entire power system. This may become a trend or transition method under the current power market conditions, in which much remains to be improved. Although these deployments have increased the cost of renewable energy for investors, they have also supported energy storage industry development.

Peng Peng, secretary general of the China New Energy Power Investment and Financing Alliance, told reporters that in the past, provincial policies requiring energy storage allocation with renewable generation did not provide any subsidies for energy storage, and that Qinghai’s policy is the first to do so. This is a big step forward for the industry.

However, one anonymous expert from the Energy Research Institute at the National Development and Reform Commission believes that the subsidy policy issued by Qinghai can only partially solve the problem of excessive energy storage allocation costs, and cannot completely resolve all disputes over renewable energy and energy storage allocation. Additional points of contention when pairing renewable energy and energy storage include the proportion of energy storage capacity which should be required for each system, and the manner in which energy storage should be deployed.

Lack of Assessment Standards for Energy Storage Systems

According to data from the National Energy Administration, during the first three quarters of 2020, Qinghai’s solar curtailment was 940 million kWh, a rate of 7.0%, and a year-on-year increase of 1.2%. The rise of the curtailment rate makes the need for energy storage increasingly urgent. The release of Qinghai’s new subsidy policy will help to increase industry willingness to deploy energy storage.

While the current version of the policy makes clear provisions on subsidies, it does not put forward specific indicator requirements for the energy storage system. Li Zhen told reporters that energy storage is an emerging technology, and related standards are gradually being established. At present, standards have been released for the construction, grid connection, and testing of energy storage stations. Regions may set corresponding entry thresholds in accordance with national standards to ensure the construction quality of the energy storage system. In addition, because Qinghai’s policy will subsidize energy storage based on the amount of electricity generated rather than subsidizing initial investment, there is decreased risk of fraud related to deployment of substandard or inadequate energy storage systems.

According to Li Zhen, "If we calculate according to the requirements of the “Notice,” which ensures that energy storage facilities are utilized for no less than 540 hours, then an energy storage system discharging for 2 hours a day will see utilization of 270 days or more. As the ancillary services market and spot market develop and improve, energy storage may participate in primary and secondary frequency regulation. With a certain amount of profits guaranteed, energy storage application scenarios will become more varied, and investment recovery and project profitability will become more feasible. As long as there are reasonable market applications, we can avoid the possibility of bad market entities driving out good ones, and more investment will be driven into the market to build more high-quality energy storage projects."

Peng Peng believes that market maturity cannot happen overnight. In the early stages in which data is lacking and experience is limited, only a simple management model can be used for an initial batch of projects, followed by a gradual refining of management. Therefore, for the time being, there are only subsidies, without standards and management regulations. Although some companies may adopt lower-priced energy storage equipment out of cost considerations, the possibility of compensation being awarded to substandard projects is unlikely under the current diversified regulatory methods.

Huang Bibin stated that as a "Notice", it is not necessary to clarify all contents. In the future, as more projects are advances, policies on construction quality or grid-connected standards may be issued, as well as detailed implementation rules for subsidies.

Policy Implementation Requires Refinement

As the first domestic subsidy policy addressing energy storage and renewable generation pairing, many difficulties may still arise in the specific implementation process.

One industry expert interviewed agrees that to receive the subsidy, electricity sold to the grid must be electricity that is within the province. But determining what electricity is considered “provincial” is a problem. As the anonymous expert stated, “Is it possible to consider all power which is not transmitted by UHV lines as part of ‘provincial’ power? The policy requires further refinement in order to answer this question."

In addition, according to the "Notice", power dispatched by electrochemical technologies in “renewables+storage” and “hydropower+storage” projects will no longer participate in Qinghai's annual direct power trading market, but will instead have payment settled through Qinghai’s renewable energy settlement base price. According to the anonymous expert above, "It is not explained how the base price is determined. I personally assume that it will be the average settlement price for renewable energy. However, whether this average price will be based on "wind+solar," "wind+solar+hydropower," or just simply ‘solar’ still needs to be clarified. "

Energy storage is still in the early stages of development. The main factor restricting the deployment of energy storage paired with renewable generation is that the cost of energy storage is not transmitted through a reasonable market mechanism, and that the full benefits of energy storage cannot be fully realized under the current structure. Although the "Notice" provides clear utilization hours and subsidy criteria for energy storage, Li Zhen believes that subsequent implementation rules are needed to ensure successful policies and guarantee the benefits of energy storage. For example, how should energy storage utilization hours be measured? How should the income which energy storage generates be settled?

"In addition, Qinghai is the first province to construct independent energy storage stations which participate in peak shaving. This new policy does not specify charging and discharging prices for these independent energy storage stations, nor does it specify their transaction settlement mechanism. These issues need to be further refined." Li Zhen said. "Finally, over time, we also need to determine how many flexible regulation resources Qinghai needs, and how many energy storage stations need to be deployed. We also must work to further understand and create a plan for how the power grid can ensure that energy storage utilization reaches 540 hours. The clearer the policy, the more beneficial it will be to stabilize investment and create a good business environment."

Author: Han Yifei, China Energy News

Energy Storage and Renewable Energy Co-development Trends and Application Models

In recent years, as installed capacities have expanded and technologies have advanced, the cost of renewable energy power generation has dropped significantly, gradually approaching that of fossil energy and in some cases even lower than that of fossil energy. The pairing of “renewable energy + energy storage” has gradually become the consensus for future renewable energy development.

In the past two years, many provinces, cities, and regions in China have issued ancillary services construction plans and operations regulations, such as updates to the grid regulations in northwest China, updates to grid regulations and ancillary services market regulations in northeast China, regulations for energy storage engaged in peak shaving in Shanxi, rules for third-party independent participation in the north China peak shaving ancillary services trial market, updates to grid regulations in southern China, and other regulatory updates. These rules have helped to promote the healthy and orderly development of the power ancillary service market, and have provided a platform for new market players and new technologies such as energy storage to participate in the power market. For example, Zhejiang has carried out transactions for ancillary services such as frequency regulation, voltage regulation, backup, and black start, explored a joint clearing model for ancillary services and the spot market, and optimized the marginal clearing of electricity and ancillary services.

In addition, over the past two years, more than ten provinces including Inner Mongolia, Hubei, and Henan have issued policies requiring new renewable energy projects to be equipped with 5%-20% energy storage systems to promote renewable energy + energy storage applications.

Renewable Energy + Energy Storage Application Business Models

Centralized wind/solar stations + storage application models typically engage in services such as peak shaving, capacity firming, grid support, and output smoothing. Current profit points include load shifting during limited power periods, priority dispatching, and reduction of thermal power spinning reserves. Potential profit points include revenue from solar-storage and wind-storage and from participation in frequency regulation and ancillary services. The advantages of these application models are that they can limit the risk of generators being penalized. However, the true value of lowering such risks is difficult to assess, and there is no compensation mechanism to measure the value created by energy storage. Economical projects are also difficult to guarantee. Additional challenges include a lack of rational investment undertaken by the power generation side, a lack of supporting policies, a lack of a market mechanism, and a lack of large-scale energy storage planning.

Xinjiang is one example. On May 26, 2020, the Xinjiang Development and Reform Commission issued the "Interim Regulations for Generation-side Energy Storage Management in the Xinjiang Power Grid," encouraging power generation companies, power sales companies, power consumers, and independent ancillary services providers to invest in the construction of energy storage facilities with a required charging power of 5000kw or more and continuous charging time of 2 hours or more. The interim regulations provide four basic principles or application models, namely, market bidding, inter-plant transactions, bilateral negotiations, and grid dispatch. Of these, the main operations rules which are used include market bidding by wind farms/solar PV as well as bilateral negotiations between power generation companies and energy storage. The regulations help to encourage the power grid to increase basic dispatching time by 100 hours annually.

These wind-storage and solar-storage stations enjoy two kinds of profit models. The first is the self-use of energy storage capacity at the wind or solar station where it is located, dispatching energy as if it were generated by the plant, and generating revenue according to the generator’s contracted price. The other type of profit model is generated when the energy storage facility enters a charging state according to the instruction of the power dispatch agency, and receiving compensation for the amount of power charged. Standard compensation for this model is 0.55 yuan/kWh.

In addition to the front-of-meter energy storage in Xinjiang, the industry has also taken note of the “shared energy storage” commercial operations model in Qinghai. This model allows renewable energy plants and energy storage enterprises to sign a transaction contract specifying time, quantity, and price of energy being traded, and cooperating with the power grid to allow dispatch of energy storage.

Rather than limiting energy storage applications to the generators at which they are co-located, a more flexible business model can be created which forms independent energy storage system operators. These specialized companies would engage in the selection, financing, design, construction, operation, and maintenance of energy storage power stations. In actual operation, energy storage operators would need to cooperate with power generation enterprises to form "virtual" connections, that is, energy storage systems would not need to be physically connected with generators, but could form a unified body of power generation enterprises at the grid-side so that generators and energy storage systems can provide high quality ancillary services. A win-win for energy storage operators and power generation enterprises can be achieved by sharing the compensation received for providing ancillary services.

Three models can be derived from this: In the first, a single power generation company and a single energy storage operator cooperate with a clear relationship and direct cost settlement. In the second model, one power generation company cooperates with multiple energy storage operators. In this model, power generation companies can make full use of the advantages of energy storage technology, and even use the variety of energy storage resources at their disposal to meet the demands of different ancillary services, thereby maximizing the quality of ancillary services provided. However, this type of cooperation model is technically more complicated, creating challenges for the operation and management of power generation. In the third model, multiple power generation companies cooperate with one energy storage operation company. The foundation of this business model is that the energy storage operator has built a larger capacity and module-divided energy storage station, and the energy storage operator may choose its best quality partner. However, this type of model presents a certain degree of complexity in business operations.

New Energy Storage Policies and Trends in China

Energy storage development in China is seeing new trends emerge.

First, energy storage technology is a multi-disciplinary, multi-scale integration of science and technology. Chemical and physical energy storage technologies involve electric power, machinery, control and other aspects. Energy storage materials, units, systems and other components require multi-disciplinary cross-integration. This cross-integration will become a major trend as new technologies are developed and existing technologies improve.

Second, there are currently a variety of energy storage technologies, which may become centralized on a handful of mainstream technologies in the future. At the same time, new technologies will continue to emerge. Whichever energy storage technology will dominate the market will be a matter of the market “voting with its feet.”

Third, the price of energy storage is rapidly falling. Only under the precondition that both renewable energy and energy storage prices continue to fall can renewable energy + energy storage become an established business model.

In the future, energy storage and renewable energy will see integrated development. Renewable energy development in China will pass through three stages, namely, the subsidy support stage, the renewable energy parity stage, and the renewables + storage parity stage. Only when the renewables + storage price (parity) and performance (dispatchability) become comparable to fossil energy will the era of mainstream renewable energy truly arrive.

Energy storage itself will also pass through four stages of development: a technical verification stage, an applications demonstration stage, an initial commercialization stage, and a large-scale development stage. Energy storage in China still faces some major challenges, such as safety concerns, a lack of clarity on what entity should be responsible for energy storage management, a lack of a reasonable price mechanism that can properly compensate storage’s value, an incomplete support mechanism for participating in the energy market, and other challenges.

To meet these challenges, we must first clarify what entity will be responsible for ensuring the safety of energy storage systems, and what entity will be responsible for overall management of energy storage projects. Comprehensive safety evaluations of energy storage systems should be conducted, identifying safety hazards at each segment of the energy storage system, and determining proper management methods for minimizing such hazards. In addition, we must also make use of project experience and our knowledge of current market development to improve standards and regulations for energy storage, and raise the threshold of entry for energy storage products in the market.

Second, we must clarify the identity of energy storage as a market entity. This includes defining the procedures for establishing energy storage projects, including fire safety approval, environmental assessment, land approval, facility approval, civil air defense approval, and other procedures. Grid companies must also clarify the procedures for grid connection of energy storage across various storage applications.

Third, a reasonable price mechanism must be defined. The value of the public good brought by energy storage is far greater than its cost. But if only a single market entity is responsible for the cost of energy storage, benefits are likely to be less than the total cost of investment. Therefore, we must look at the cost and value of energy storage from an overall perspective, making decisions at the national level and based on the principle that the beneficiary should be the one to pay for services. These actions will help to establish a reasonable market-oriented price mechanism shared by generators, the grid, and consumers.

Facing the challenged of energy storage commercialization across many fields, we must continue to accelerate the power marketization process, use market-based means to solve challenges in energy storage system applications, and rationalize market rules to adapt to new technologies such as energy storage. The ancillary services market and demand-side management, particularly the long-term demand response mechanism, are still waiting to be fully established in order to increase the value of energy storage applications across various fields. In the initial stages of marketization, it is also necessary to provide financial assistance to energy storage to support the social benefit it brings. We have three primary suggestions for the development of energy storage:

At the current stage, we must be engaged in forward-thinking planning and research to avoid ineffective allocation of resources. We must make clear the threshold of entry for energy storage in the market to ensure only high-quality energy storage applications are developed. We must also implement policies for paired energy storage applications which will support co-development of storage with renewable energy generation.

In the short term, with the power market and price mechanism still unable to reflect the value of paired energy storage systems, we must promote pumped hydro storage polices and introduce transitional polices which will support renewable energy and energy storage co-development. We suggest that an energy storage quota mechanism should be explored, and the importance of “green power” should be emphasized. China's green certificate trading and renewable energy quota mechanism should be used as a reference.

Finally, in the medium and long term, the price of renewable energy power generation and the cost of energy storage must be paid by its beneficiaries. Price compensation is also necessary to promote the co-development of renewable energy and energy storage. We suggest the establishment of a long-term market-oriented mechanism and an energy storage price mechanism which considers the holistic perspective to properly assign the payment for “green value” to those which benefit most from it.

Author: Chen Haisheng, Chairman, China Energy Storage Alliance

2020 China Energy Storage Policy Review: Entering a New Stage of Development in the 14th Five-year Plan Period

Under the direction of the national “Guiding Opinions on Promoting Energy Storage Technology and Industry Development” policy, the development of energy storage in China over the past five years has entered the fast track. A number of different technology and application pilot demonstration projects have been launched, many key technical components have reached an advanced level of maturity, numerous key technical norms and standards have formed, and internationally competitive market players have entered the playing field. While it is true that the development of China's energy storage industry has moved from a technical verification stage to a new stage of early commercialization, the industry still faces many challenges which hinder development, and true "industrialization" has not yet materialized. As we enter the 14th Five-year Plan period, we must consider the needs of energy storage in the broader development of the national economy, increase the strategic position of energy storage in the adjustment of the energy structure, and make known the important role of energy storage in the social and economic development of China. While looking back on 2020, we also looking forward to the development of energy storage industrialization during the 14th Five-year Plan, as policy and market mechanisms become the key to promote the full commercialization and large-scale application of energy storage.

Build a solid foundation for the training of talents and increase the strategic importance of energy storage

In 2020, under the direction of the National Development and Reform Commission to promote energy storage and lay a solid foundation for industrial development, the Ministry of Education, the National Development and Reform Commission, and the Ministry of Finance jointly issued the “Action Plan for Energy Storage Technology Discipline Development (2020-2024),” proposing to create a number of undergraduate majors, secondary disciplines, and cross-disciplines specializing in energy storage technology over the next five years. Xi'an Jiaotong University, North China Electric Power University, and other colleges and universities have already added such energy storage disciplines. The “Suggestions on Accelerating the Reform and Development of Postgraduate Education in the New Era” also included the construction of an innovative platform for the integration of energy storage technology, industry, and education, and implements a special project for independent training of talents in core technical areas. The construction of a discipline system and the training of professionals through these policies will help to build a solid industrial foundation for energy storage.

Industry development guidance and pursuit of optimal energy prices

In July 2020, the National Energy Administration issued the “Notice on Organization and Application of Scientific and Technological Innovation (Energy Storage) Pilot Demonstration Projects.” The issuance marked the conclusion of a years-long solicitation of national energy storage demonstration projects with the shortlisting of eight large-scale energy storage projects in a range of applications. The demonstration projects will help to promote the introduction of new policies and market mechanisms through analysis and synthesis of successful experiences and current challenges relating to a diverse range of energy storage projects.

The National Development and Reform Commission and the National Energy Administration proposed a "two integrations" energy development strategy in the “Guiding Opinions on the Development of ‘Integrated Wind, Solar, Hydro and Thermal Storage’ and ‘Integrated Source, Network, and Load’ (Draft for Comment).” The proposal combines the advantages of different energy technologies with the rapid and flexible adjustment capabilities of energy storage. However, the pursuit of low energy costs through the "two integrations" strategy is not realistic in the short term. We must also consider the value and cost of the societal benefits of the green development which these projects bring. Promoting the construction of an intelligent, efficient, and green energy system requires the entire nation to accept and bear these comprehensive costs and set aside the single pursuit of only the absolute lowest energy costs.

Continued electricity market reforms create an open and fair environment

As electricity market reforms continue, market rules gradually tilt to new market players such as energy storage. The “Basic Rules of Medium-and Long-term Electric Power Trading” defines the identity of energy storage enterprises participating in market transactions. Jiangsu, Jiangxi, Shanxi, Qinghai, and other regions have released construction plans for electric power spot markets and proposed long-term development directions for ancillary services markets. Among these proposals, "establishing a market mechanism for ancillary service costs shared by users and power generators" has become the key for promoting the commercial application of energy storage in the future. The “Notice on the Signing of Medium-and Long-term Electric Power Contracts in 2021” proposes to promote medium-and long-term transactions with load curves on both the generator and user side. Because it is difficult to predict market supply and demand in the short term, it is still necessary to refer to the existing catalogue electricity price or guiding electricity price to determine the peak and off-peak price difference. Although China has carried out medium-and long-term trading for many years, and has also put forward the idea of transitioning to a new price model, there are still some regions where the price formation mechanism does not match the actual power supply and demand. The peak and off-peak price gap has also been reduced through medium-and long-term transactions, which also reflects the passivity of the market mechanism. In the future, the trend of widening the peak and off-peak price gap will continue according to power supply and demand. Behind-the-meter energy storage arbitrage business models will still have guaranteed value, though the ability of energy storage to participate in spot market bidding must also gradually improve.

Under the guidance of the “Work Plan for Improving the Power Ancillary Services Compensation (Market) Mechanism,” ancillary services markets have been constructed in multiple regions in recent years, and energy storage has also been commercialized in Guangdong, West Inner Mongolia, Shanxi, North China, and other regions. However, the high compensation brought by the provision of high-performance energy storage services also creates risks for market capital use, and the continued adjustment of policies has also impacted investment in energy storage projects. In 2019, adjustments were made to the compensation calculation in West Inner Mongolia and North China. In 2020, Guangdong also made an adjustment to its settlement process, while West Inner Mongolia once again adjusted its compensation calculation method. Shanxi, Qinghai, Hunan, and other regions have also made downward adjustments to the peak regulation compensation standards for energy storage participating in ancillary services. Policies have changed frequently in less than a year. This lack of a long-term market mechanism has become a prominent problem restricting the commercial development of energy storage.

Despite this, ancillary service market rules solve the basic identity problem of energy storage participating in the market. Energy storage receives a market subject status equal to that of power generation enterprises, power sales enterprises, and power users, and third parties are permitted to offer their services to the market. Independent energy storage providers in Fujian, Jiangsu, Shanxi and other regions are permitted to apply for power generation business licenses, and are permitted to participate in ancillary services provision.

Renewable energy + energy storage becomes a leading trend, but commercial development still faces difficulties

As large-scale renewable energy continues to expand, the pressure and responsibility to supply guaranteed power generation becomes more intense. In 2020, numerous local governments and power grid departments once again put forward a demand for renewable energy projects to be equipped with energy storage systems matching 5% to 20% of renewable energy generation capacity. Energy storage has also become a precondition for priority grid connection and priority consumption. However, under existing system costs and without a mechanism in place for assigning cost coverage responsibility, the development of integrated renewables and storage cannot be achieved overnight. Relying solely on the principle that "charge and discharge electricity prices and settlement shall be determined in accordance with relevant national regulations" cannot solve commercial development challenges, but instead shows that policy is oriented towards transferring responsibility. During the process of charge and discharge, energy storage switches identity from that of a user to that of a power generator. Peak-shaving compensation and feed-in charges cannot be paid repeatedly, while independent energy storage projects are also faced with the risk of double charges. In addition, policy must also gradually raise the threshold of entry for projects in the market to avoid the possibility of safety accidents inhibiting industry development.

It is not necessary to use market mechanisms and policy compensation to give specific support to energy storage. Instead, energy storage should be allowed a fair and open market in which it is allowed to compete with other market entities. A sound market environment is the core for comprehensive commercial development of energy storage.

Electricity prices are optimized and adjusted, and behind-the-meter energy storage prices becomes more reasonable

A new round of transmission and distribution electricity price and retail electricity price adjustments resulted in numerous regions reducing consumer electricity prices, adjusting peak and off-peak price differences, and adjusting the peak and off-peak price implementation period. With the large-scale deployment of renewable energy, the original mode of determining peak and off-peak electricity prices according to consumer electricity consumption habits has changed, and net load has become the basis for peak and off-peak price adjustment. In 2020, Jiangsu, Zhejiang and other regions further reduced the off-peak electricity price and widened the peak and off-peak price gap. Regions such as Hubei not only widened the peak and off-peak period, but also added a super peak electricity price and adjusted their peak and off-peak price differences. Shandong, Gansu and other regions implemented complete price adjustments for all TOU periods. While the widening of the peak and off-peak price difference is beneficial to behind-the-meter energy storage applications, energy storage charge and discharge strategies must also be adjusted to adapt to the changes to the peak and off-peak period.

At the same time, Beijing’s Chaoyang District continued to provide 20% initial investment subsidies for energy storage projects after energy storage was incorporated into the special funds for energy conservation and emission reduction in 2019. After Hefei, Suzhou, and other regions granted subsidies for distributed solar+storage and energy storage systems, Xi'an and Shaanxi begin providing 1 RMB/kWh charging subsidies for energy storage in solar+storage systems. Energy storage technologies are also needed in new applications such as 5G base stations, data centers, and EV support facilities. Consumers in these industries will rely on energy storage to help solve distribution capacity problems, provide emergency power backup, and reduce electricity expenditures. Related energy storage applications can also receive regional subsidies in Guangdong, Kunming, Hefei and other regions. With the increasingly widespread use of EVs, further integration of solar+storage+charging can also be expected.

Demand response and consumer peak shaving overlap, and adjustment resources require increased efficiency

The peak-shaving market is expected to connect with the spot market mechanism, using market-oriented price mechanisms to mobilize resources to respond to the demands of the power system. However, to mobilize behind-the-meter adjustment resources, power operations regulators in Shanghai, Jiangsu, Guangdong, Zhejiang, Shandong, and Henan launched the construction of a demand response mechanism based on the 2013 demand response trial program. Compensation comes from surplus capital pools such as super peak electricity prices and renewable energy transactions. In addition, energy regulatory departments in North China, Jiangsu, and Shanxi opened the door for third-party entities and consumer resources to participate in peak-shaving ancillary services, though peak-shaving compensation in some regions is still provided by power generation enterprises. In areas in which ancillary services costs are not transmitted to the consumer, there are policy change risks for non-generation entities which earn profits from ancillary services.

Due to the high overlap between demand response execution time and peak and off-peak electricity prices, there is still room for flexible design of the baseline, so the profits for energy storage participating in demand response are relatively limited. The existing peak shaving and demand response mechanism design provides energy storage charging and discharging compensation which can increase energy storage revenue. However, under the existing peak and off-peak price mechanism, independent energy storage charging and discharging for peak shaving is already in place. If peak shaving and demand response implementation are consistent with the implementation of peak and off-peak price periods, there will be some overlap in compensation. In addition, although peak shaving and demand response are directed by different departments, the response mechanism is basically the same, and there is still the problem of compensation payments duplicating. In some regions, peak shaving is frequently dispatched, with cumulative days equaling as much as half a year. A resource response that was originally a short-term emergency service has become a continuous demand. Rather than continue this practice, it would be better to flexibly change the peak and off-peak pricing period and prices, and allow users to cover the cost of energy storage. Therefore, it is necessary to integrate the process of spot market construction to effectively link consumer peak shaving, demand response, and market-based pricing mechanisms to avoid overlapping use of resources and invalid payment of funds. The baseline and response mechanism should be adjusted reasonably to support the energy storage technology as it provides services to the power system.

The power grid supports the development of energy storage and promotes its role in the energy system

In 2019, the national government made it clear that “costs unrelated to the power transmission and distribution business of grid companies,” including the cost of energy storage facilities, should not be included in transmission and distribution prices. China’s major grid companies followed by stating they would not carry out grid-side electrochemical storage investment, leasing, or contract energy management, nor would they construct new pumped hydro storage projects. Currently, due to the inability to match regulatory capabilities with the demand for grid investment in energy storage projects, it is reasonable to prohibit grid investment in energy storage projects under the principle of ensuring market fairness. However, this does not mean that the regulatory mechanism is not evolving. In 2020, the method by which the power grids promoted energy storage development changed. In the “Key Work Arrangements for Reform in 2020” and the “Opinions of State Grid Co., Ltd. on Comprehensively Deepening Reform and Striving for Breakthroughs,” the power grid expressed its intention to implement a new business plan for energy storage and cultivate new momentum for growth based on strategic emerging industries such as energy storage. The “Key Points for Professional Work on Smart Power Utilization in 2020" also suggested strengthening customer-side energy storage application research and gradually clarifying system access requirements. In addition, the “Energy Law of the People's Republic of China (draft for comment)” encouraged the development of smart grid and energy storage technology. The National Energy Administration's response to Recommendation No. 9178 of the Third Session of the Thirteenth National People's Congress stated that for some energy storage projects deployed to defer investment in new transmission lines and substation equipment, consideration will be given to include their construction and operations costs into T&D service costs. The response also suggested that continued research would seek to create an effective model for covering the costs of energy storage in order to support the orderly development of grid-side storage.

Implementing large-scale commercial development of energy storage in China will require significant effort from power grid enterprises to promote grid connection, dispatching, and trading mechanisms, and also share the responsibility of the regulatory authority for energy storage safety risks to ensure the high-quality application of energy storage.

How Can Energy Storage Overcome Obstacles to Participation in the Ancillary Services Market?

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In November 2020, the Central China Energy Regulatory Bureau released the “Jiangxi Province Power Ancillary Services Market Operations Regulations (Trial)” (referred to as the “regulations” below). In comparison to the earlier draft release, the trial regulations have added content which encourages independent energy storage systems to participate in the peak shaving ancillary services market.

Since the National Energy Administration’s 2017 publication of the “Improving Power Ancillary Services Compensation (Market) Mechanism Workplan,” multiple regions have followed with market operations regulations for ancillary services, providing support for energy storage technology applications. Considering these developments, what is the current status of the ancillary services market in China? What challenges remain to be resolved?

Independent Energy Storage Has Advantages

Industry experts believe that although the release of the Jiangxi regulations provides clarification of energy storage’s identity, the compensation mechanism and subsidies for energy storage provided in the regulations are not enough to cover the investment costs for storage. Market regulations help clear obstacles related to energy storage’s identity, but do not provide simple price compensation.

“Independent energy storage stations are an emerging trend. When energy storage is tied to other systems, it must share its earnings with those other systems,” China Energy Storage Alliance senior policy research manager Wang Si told reporters.

Wang Si believes that independent energy storage possesses two advantages. First, companies which invest and operate independent energy storage systems may operate projects on their own, collecting earnings for themselves with a greater degree of flexibility. Second, independent energy storage systems are better able to aggregate, creating greater value through energy storage sharing. This changes the conventional business model of providing service for just one user, allowing an energy storage system to instead provide service for multiple generation companies, users, and even the entire power system. “Therefore, it is necessary to not only design such systems, but also allow them to participate in the ancillary services market. This will increase the overall effectiveness of the systems,” said Wang Si.

According to Wang Haohuai, director of the China Southern Grid Power Dispatch Center, “with energy storage’s identity in the market defined, operator autonomy is increased. Otherwise, operations and settlement are limited by the entity to which the storage system is tied to, which will affect enthusiasm for investment.” As Wang Haohuai also stated, energy storage follows market service regulations. Implementation of a pay-for-performance mechanism should also be guided by a top-to-bottom evaluation or market mechanism. “For example, once large-scale renewable energy penetrates the grid, exactly how much peak shaving and frequency regulation resources are needed, and how fast, accurate, and stable must they be? Only when operations, market, and settlement provisions have established relevant indicators will energy storage be able to achieve a sufficiently fast regulatory speed and earn a higher level of compensation.”

The Energy Storage Cost Mechanism Continues to Face Challenges

Energy storage has yet to reach a fully commercial stage, making marketization of ancillary services a challenge to commercial operations of energy storage.

According to Wang Si, the key to solving the problem of ancillary services commercialization lies in the power market. Current market regulations and related policies do not support market entry of energy storage. This is especially true of ancillary services market and spot market regulations, which cannot support the full participation of storage in the market, nor allow it to receive full benefits. “Following power market reforms, barriers to energy storage’s participation in the market were removed, and new doors were opened for energy storage to earn profits. We predict that energy storage costs will continue to decline, particularly since the large-scale effect of energy storage in the power system has yet to be reflected.”

Wang Si went on to state that energy storage’s costs should not be incorporated in power costs, “in the current renewable energy quota system, it is the consumers who are made to bear the duty of using green electricity, and the corresponding costs are reflected in financial products such as green certificates. In the future, power generators will gradually transmit the cost to the consumer side, and receive payment from the beneficiary. To support the development of renewable energy and energy storage, corresponding policy support is needed to generate economies of scale, further reduce costs, and enhance competitiveness."

According to Wang Haohuai, the power market system is currently under construction, and the commercial value assessment of energy storage is undergoing major policy changes, creating both risks and opportunities. For example, in addition to the challenges of the “pay-for-performance” mechanism, there are also issues such as the inability to transfer energy storage costs to the consumer, preventing the beneficiary from being the one who pays. “Combined energy storage and renewable energy costs are still high at the current stage. In order to promote green energy consumption, consumers must take on the costs of green energy development.”

Policy Changes Bring Investment Risks

Ancillary services include frequency regulation, peak shaving, operating reserves, voltage control, blackstart, and other services. Among these, peak shaving is a unique service in China. Peak shaving is the practice of short-term regulation of power to match output generation with changing load, balancing power and encouraging greater consumption of renewable power. “Whether peak shaving and spot markets will be integrated in the future or will function in parallel is a matter of discussion among experts,” said Wang Haohuai.

Electricity market rules have not yet formed a long-term mechanism. Marketization is still at a transitional stage, which puts projects with a long investment payback period at risk when regulatory changes occur. “Everyone invests in energy storage projects under the current regulatory system, so they also face greater risks from policy changes,” said Wang Si.

Wang Si pointed out that the release of ancillary services market operations regulations across many regions has given energy storage an opportunity to expand profit margins to a certain extent, but that the vast majority of policies and regulations cannot offer compensation which fully covers investment costs.

“We have not yet completely entered the spot market stage. It is necessary to provide value compensation to combined renewable energy and energy storage through ancillary services market policies. This is the reason why many regions have released ancillary services market operations regulations,” Wang Si said, “we hope to see ancillary services market regulations gradually become a long-term mechanism, embodying the basic principle of paying for results, paying for revenue, or paying for accidents, and supporting transaction, grid connection, and settlement stages. Such regulations will help to clear away obstacles to energy storage’s participation in the market.”

CNESA Global Energy Storage Market Analysis—2020.Q3 (Summary)

As of the end of September 2020, global operational energy storage project capacity (including physical, electrochemical, and molten salt thermal energy storage) totaled 186.1GW, a growth of 2.2% compared to Q3 of 2019. Of this global total, China’s operational energy storage project capacity comprised 33.1GW, a growth of 5.1% compared to Q3 of 2019.

Graph 1: global total operational energy storage project capacity (MW)

Graph 1: global total operational energy storage project capacity (MW)

Graph 2: China’s total operational energy storage project capacity (MW)

Graph 2: China’s total operational energy storage project capacity (MW)

Both in the international market and the Chinese market, pumped hydro storage continued to account for the largest proportion of energy storage capacity totals. Yet the share of pumped hydro has been on a steady decline, with international pumped hydro capacity decreasing 1.9% and Chinese pumped hydro capacity decreasing 3.4% compared to 2019 Q3. In contrast, electrochemical energy storage capacities continued their rising trend, with international capacities increasing by 1.7% and Chinese capacities increasing by 2.7% compared to 2019 Q3. Total global energy storage capacity reached 10,902.4MW, while China’s total energy storage capacity reached 2242.9MW, surpassing the 2GW mark for the first time.

In the first three quarters of 2020 (January – September), global newly operational electrochemical energy storage project capacity totaled 1,381.9MW, an increase of 42% compared to the same period in 2019. Of this global capacity, China launched 533.3MW of newly operational electrochemical storage, an increase of 157% compared to the same period in 2019. In a global comparison, China led the world in new energy storage capacity, comprising 38% of new growth. Among technologies, Li-ion batteries comprised 99% of new capacity both in the global and Chinese market. Among applications, grid-side energy storage was most prevalent globally, comprising over 1/3 of new capacity, while in China renewable energy generation-side projects were most prevalent, comprising 2/3 of new capacity.

About this Report

CNESA Research customers can access the full version of the CNESA Global Energy Storage Market Analysis – 2020.Q3 by visiting the ESResearch website.

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2020 Energy Storage West Forum Held in Xining - Exploring an Ancillary Services Market Development Path in Support of High Grid Penetration of Renewable Energy

On Sep 28, the China Energy Storage Alliance hosted the 2020 Energy Storage West Forum in Xining, Qinghai, with support from the China Energy Research Society Energy Storage Committee, British Embassy Beijing, and China Huaneng Group Renewable Energy Technologies Research Center.

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China’s western region is one of the country’s important clean energy generation bases and a key component to the Belt and Road project. As the coordinated development of renewable energy and energy storage becomes a driving trend, the abundant renewable energy resources in the west and the promotion of energy storage technology applications will inevitably become important supporters for the rapid development of energy storage in China. In addition, as the coordinated development of renewable energy and energy storage becomes a driving trend, the ancillary services market mechanism (in its transitional stage) becomes an important policy guarantee for integrated renewable energy and energy storage applications.

This year’s forum focused on the theme “Exploring an Ancillary Services Market Development Path in Support of High Grid Penetration of Renewable Energy,” featuring discussions examining ways to integrate ancillary services and energy storage. The forum provided support for China Energy Storage Alliance’s current research on ancillary services market development for high renewable energy penetration in China, which is guided by the National Energy Administration and supported by the UK China Prosperity Fund Energy and Low Carbon Economy Programme. The forum also gathered industry colleagues devoted to the development of the western energy storage market together to explore ways to better create innovative energy storage applications in the west, and provide western regional governments with support to implement policies beneficial to energy storage. These discussions help contribute to the establishment of a system and mechanism for commercial applications of energy storage that meets the characteristics of the northwest region.

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Opening addresses were delivered by leaders from the National Energy Administration, Qinghai Energy Administration, Haixizhou Energy Administration, the British Embassy Beijing, China Huaneng Group Renewable Energy Technologies Research Center, and the China Energy Storage Alliance. CNESA secretary general Liu Wei hosted the forum’s opening session. Liaoning Power Grid former lead engineer Wang Zhiming served as host for the keynote sessions.

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The opening ceremony began with remarks from Lei Xiang, researcher at the Department of Science and Technology Equipment, National Energy Administration. Mr. Lei stated that energy storage development has now entered the beginning stages of commercialization. The importance of energy storage to the energy system transition has begun to become apparent, but technological, economic, and safety barriers, as well as the lack of a mature market mechanism, are still major challenges. There are five major areas which require improvement: first, strengthening of overall planning to create a mechanism which increases clean energy generation and consumption that is supported by energy storage. Second, strengthening of power market mechanisms, creating a positive development environment for commercial operations of energy storage. Third, optimizing dispatch operations mechanisms to promote the paired operations of energy storage and clean energy. Fourth, creating a technical standards system which will support sustainable industry development. Fifth, supporting the development of pilot projects in key regions to find new models for the future of energy storage.

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Zhou Wu, vice director of the Qinghai Energy Administration, said that Qinghai has been exploring the use of 100% clean energy for many years, in the past achieving world records by running on 100% renewable energy for separate periods of seven, nine, fifteen, thirty, and 100 days. To ensure a long-term stable supply of large-scale renewable energy, an ancillary services market powered by energy storage is indispensable. Mr. Zhou stated that the Qinghai Energy Administration would continue to promote the development of the Qinghai energy storage market.

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Ang Zhi, director of the Qinghai Haixizhou Energy Administration, stated that Haixizhou renewable energy capacity, both under construction and in operation, totaled 12.99 million kilowatts. Haixizhou is currently planning the implementation of a variety of energy storage projects, and has already reached 125,600 kilowatts of installed energy storage capacity. Haixizhou has achieved a great deal of development potential in the green energy sector, and possesses the basic conditions needed to carry out national plans for “green energy + energy storage.” The prospects for development and application of energy storage technologies are broad. Pumped hydro storage, electrochemical storage, hydrogen storage, and compressed air energy storage technologies all show potential for application in Haixizhou.

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Conor Gask, head of renewables and power sector at the British Embassy Beijing, joined the forum through prerecorded viedo. Mr. Gask stated that both China and the UK are world leaders in clean energy technologies, and that cooperation and information exchange between the two countries is important to achieving the rapid deployment of clean energy technologies. Through the support of the UK government’s China Prosperity Fund Energy and Low Carbon Economy Programme, CNESA is currently developing a national roadmap for ancillary services market development. This roadmap will support greater flexibility in the grid as well as greater penetration of renewables. Mr. Gask expressed hope that the project would contribute to China’s carbon reduction goals, and would encourage greater collaboration between China and the UK in energy storage, ancillary services market design, and broader energy system reforms.

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Ren Libing, secretary of discipline inspection at the China Huaneng Group Renewable Energy Technologies Research Center, stated that energy storage is an effective means for promoting the energy revolution, providing flexible peak shaving services, tackling curtailment issues, and increasing grid safety. The Huaneng Renewable Energy Technologies Research Center has been involved in energy storage research for more than 10 years, and currently has more than 300MWh of energy storage capacity both under construction and operational. The research center’s current focus is on the theme “New Strategies for Energy Safety,” promoting the use of innovative development in clean energy sources and working to contribute to a sustainable and efficient energy storage industry.

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Yu Zhenhua, vice chairman of the China Energy Storage Alliance, stated that western China features excellent renewable energy resources, and has been the setting for many innovative energy storage models in recent years. The region is well-suited for exploring renewable energy and energy storage paired development models. There is no doubt that renewable energy capacity development goals are beneficial to energy storage, yet energy storage still faces many challenges such as the lack of a clear identity, a lack of market diversity, and lack of a long-term mechanism for sustainability. These challenges must all be confronted and overcome. Chairman Yu also said that top-level energy development plans are still based on past experiences and understanding, while the current fast-paced development of energy storage signifies that future 10-year and 30-year energy planning goals and energy storage structure goals may require adjustment.

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Li Hong, professor at the Chinese Academy of Sciences Institute of Physics, stated that China possesses strong determination to develop renewable energy, smart grids, and an Internet of Energy. Development of energy storage is strategically important to help optimize China’s energy structure and increase energy safety. The “Fourteenth Five-year Plan” hopes to increase the safety, lifespan, power rating, and energy efficiency of energy storage technologies, as well as improve response times and bring costs to below .2 RMB per kilowatt hour. As development continues, those companies which possess the greatest technological competitiveness, the most practical experience, and the strongest ability to integrate resources throughout the entire life cycle and the entire industry chain will eventually become the biggest winners.

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Wang Jianxue, professor at Xi’an Jiaotong University, stated his belief that ancillary services are both technically complex and display rudimentary market coupling, making them prone to speculation. Whether ancillary services costs are reasonable and whether operations are stable are some of the key indicators of market-oriented reform. Prof. Wang stated that ancillary services costs should be apportioned to the user. For example, users which produce high levels of pollution and therefore require a greater amount of ancillary service resources than other users should be required to participate in the ancillary services apportionment mechanism.

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Liu Mingyi, energy storage project development director at the China Huaneng Group Renewable Energy Technologies Research Center, stated that in October 2019, Huaneng Group positioned energy storage as a key area of focus. Core goals include large capacities, low costs, long lifespans, high efficiency, and increased safety. Huaneng has currently created a billion-renminbi energy storage market, and in the future the group hopes to create a market in the hundreds of billions.

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Liu Mingyi and Professor Zheng Hua of North China Electric Power University were the hosts of the roundtable discussions “Exploring Development Path and Models for a Qinghai Ancillary Services Market Supporting High Renewable Penetration” and “Exploring A National Ancillary Services Market Roadmap and Mechanism Design.” Representatives from North China Electric Power University, Luneng Group, Qinghai Guangheng New Energy Co., Shanghai Electric Power Design Institute, Qinghai NEGO & Beijing NEGO Automation Technology, Zhiguang, State Grid Liaoning Dispatch Center, State Grid Ningxia Dispatch Center Control Office, Huadian Shanxi Energy Co., State Grid Jiangsu Electric Power Co. Planning and Development Research Center, and CLOU engaged in discussions on models and pathways for developing ancillary markets which support high penetration of renewables.

Additional presentations were delivered by energy storage companies and stakeholders such as Kelong, Soaring, SVOLT, Sungrow, Chungway, the Inner Mongolia Autonomous Region Electrical Engineering Society, BYD Auto Industry, and State Grid Jilin Dispatch Center. These presenters shared experiences on practical development and deployment of energy storage technologies for ancillary services applications, as well as  methods for developing a national ancillary services roadmap in support of energy storage.