The deployment capacity of global lithium battery

  • Detail

In the next five years, the deployment capacity of the global lithium-ion battery energy storage system will increase by 55% annually.

now, people in the industry have reached a broad consensus that more power level energy storage systems will be deployed in the world in the next few years. However, few people know that a new forecast is put forward in a survey report recently issued by GTM research, the industry media: the deployment capacity of the global lithium-ion battery energy storage system will increase by 55% annually in the next five years

in other words, the lithium-ion battery energy storage system will increase from 2 GWH in 2017 to 18 GWH in 2022, an increase of more than 8 times

this growth started on a very small scale. In contrast, electric vehicle sales generated 112 gigawatt hours of battery demand in 2017 alone. However, with the annual growth rate of 55%, the electric energy storage system will be sufficient to improve and change the performance of the global electrical system

the United States will continue to take the lead in the deployment of battery energy storage systems, followed by China, Japan and Australia. The investments invested by American States now include early battery energy storage projects, market reforms and energy storage regulations. In the next few years, the price of recycled waste plastics will be much cheaper than the rising price of plastic raw materials in recent years

although the electricity planning in the United States varies greatly among States, this pioneering work enables states to follow up more quickly and effectively. The centralized policies formulated by China, South Korea and other countries can make the battery energy storage system develop rapidly

a series of interrelated trends make it possible to accelerate the deployment of battery energy storage systems. The market demand for electric vehicle batteries has stimulated the large-scale expansion of battery production facilities, thus reducing the battery cost of electric applications

at the same time, the laboratory research of related technologies continues to improve the energy density by adopting the best combination of anode, cathode and electrolyte materials. Once electric vehicles have been on the road for many years, the waste batteries they produce will become cheap second-hand fixed battery energy storage equipment

so far, the cost of the energy storage system has limited its use in electricity. Except for a few special cases, it is expected to achieve an 8% annual return on investment with improving the independent innovation ability of the plastic processing industry as the core. As costs fall sharply, its broader use cases will become attractive. In the same period, the growth trend of wind and solar energy will increase the asset value of energy storage system

then the problem becomes the impact of the influx of battery energy storage system on the rest of the electricity

for example, Australia's first large-scale battery energy storage system has reduced the price of its key electricity service market in the event of a serious lightning strike. According to the research report released last year, by 2025, the battery energy storage system deployed in Australia will begin to replace the new and existing natural gas power plants, and then challenge the natural gas power plants that can generate a lot of electricity before 2035

California legislators plan to completely eliminate electricity produced by fossil fuels in 2045. In this case, battery energy storage system manufacturers will certainly become the main suppliers providing flexible capacity

Copyright © 2011 JIN SHI