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2030年储氢合金市场预测——按合金类型、类型、销售渠道、应用和地区进行的全球分析Hydrogen Storage Alloys Market Forecasts to 2030 - Global Analysis By Alloy Type, Type, Sales Channel, Application and By Geography |
根据 Stratistics MRC 的数据,2023 年全球储氢合金市场规模将达到 39.8 亿美元,预测期内復合年增长率为 13.4%,到 2030 年将达到 95.9 亿美元。达到美元。
储氢合金是可以可逆地存储氢原子的材料,可用于能源存储、燃料电池和其他运输应用等应用。 储氢合金有多种类型,每种都有优点和缺点。 最常见的合金包括钛、锆、铁、稀土和镁合金。
预计对氢气生产和储存的需求将会增长,可能会导致用于大规模能源储存的地下洞穴和用于小型储存的钢製容器。 人们对氢作为潜在可再生能源的兴趣日益浓厚,加上对氢能存储的需求不断增长,预计将推动全球市场对氢存储合金的需求。 加氢站储氢目前已广泛采用多种方法,包括储氢合金、高压氢气储存和液氢储存。
氢能存储技术的高成本和復杂性预计将成为市场的障碍。 机载氢气储存非常昂贵,特别是与传统的石油燃料储存系统相比。 此外,储氢系统需要低成本的材料和组件,以及低成本、大批量的製造方法。
最重要的元素之一是氢,它以气态存在。 近年来,人们对氢作为重要能源在各种应用中的潜在用途产生了极大的兴趣。 据燃料电池和氢能协会称,人们越来越重视用其他分布式能源替代可再生能源,这大大增加了对氢气生产和储存的需求。 此外,氢能存储是一种可以存储剩余可再生能源并可用于各种应用的技术,例如活塞发动机和燃气轮机的燃料。
价值链的中断对原材料的供应产生不利影响,并影响储氢合金市场的增长。 然而,随着经济试图重启,全球对储氢合金的需求预计将飙升。 然而,对准时生产的重视也是阻碍行业扩张的一个问题。
COVID-19 疫情改变了运营效率,扰乱了国内和国际边境快速结算的价值链,导致收入损失和损害。 《能源行业评论》的一项研究表明,与大流行相关的经济危机可能会大大推迟清洁氢能源的开发和商业化。 这也可能影响氢能行业作为能源转型中缺失环节的顺利运作的能力。
预计铝青铜 (AB5) 领域将在整个预测期内占据最大份额。 AB5型储氢合金Mm(Ni、Mn、Co、Al)5是当今广泛使用的几种合金系列之一。 MmNi3.55Mn0.4Al0.3Co0.75合金已被证明能够满足可行电池在成本、循环寿命和存储容量方面的基本要求。 AB5 合金将氢化物形成金属 A(通常为稀土金属(La、Ce、Nd、Pr、Y 或称为混合稀土金属的混合物))与非氢化物形成元素镍结合在一起。
预计铝青铜 (AB2) 细分市场的复合年增长率最高。 AB2 合金作为镍氢电池的阳极已被广泛研究。 对气相和电化学环境进行了比较,因为晶格内的氢扩散是水合过程中的决定性步骤。 关于水合引起的结构变化,我们发现每种合金中稳定相的各种偏析和晶胞特性的变化。
北美预计将占据最大份额。 汽车行业对环保技术的需求不断增长,为移动出行领域的新参与者氢带来了新的机遇,推动了北美储氢合金市场的发展。 因此,电子行业的技术进步和增长预计将在预测期内增加对储氢合金的需求。
由于生产力增长的影响,亚太地区预计将出现最高的市场复合年增长率。 亚太地区的增长经济体正在采用各种外国製造的设备来提高製造效率。 这背后是新兴国家政府大量投资等因素。 然而,这些资金旨在支持大规模基础设施计划。
2019年10月,AMG收购了钛中间合金製造商国际特种合金公司。 收购 ISA 为 AMG 提供了一个绝佳的机会,可以提高其在北美和欧洲航空航天市场的这些关键产品中的市场地位。
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According to Stratistics MRC, the Global Hydrogen Storage Alloys Market is accounted for $3.98 billion in 2023 and is expected to reach $9.59 billion by 2030 growing at a CAGR of 13.4% during the forecast period. A hydrogen storage alloy is a material that can reversibly store hydrogen atoms and is used in applications such as energy storage, fuel cells, and other transportation applications. There are many different types of hydrogen storage alloys, each with its own set of benefits and drawbacks. Some of the most common types include titanium, zirconium, iron, rare earth, and magnesium alloys.
The demand for hydrogen generation and storage is predicted to expand, potentially in underground caverns for large-scale energy storage or steel containers for smaller-scale storage. The growing emphasis on hydrogen as a possible renewable energy source, combined with rising demand for hydrogen energy storage, is likely to drive demand for hydrogen storage alloys in the global market. Several approaches, such as hydrogen storage alloys, high-pressure hydrogen gas storage, liquid hydrogen storage, and others, have been widely employed to store hydrogen at hydrogen filling stations.
The high cost and complexity of hydrogen energy storage technologies are expected to impede the market. On-board hydrogen storage devices are prohibitively expensive, especially when compared to traditional petroleum fuel storage systems. Moreover, low-cost materials and components, as well as low-cost, high-volume manufacturing methods, are required for hydrogen storage systems.
One of the most important elements is hydrogen, which is abundant in its gaseous state. In recent years, there has been a lot of interest in the possible use of hydrogen as a key source of energy in a variety of applications. According to the Fuel Cell and Hydrogen Energy Association, the growing emphasis on replacing renewables with other dispatchable energy sources has significantly increased demand for hydrogen generation and storage. Additionally, hydrogen energy storage is a technology for storing surplus renewable energy so that it can be used for a variety of applications, such as fuel for piston engines or gas turbines, among others.
The disrupted value chain has had a detrimental influence on raw material availability, affecting the growth of the hydrogen storage alloys market. However, as economies attempt to restart their operations, global demand for hydrogen storage alloys is projected to surge. Although the emphasis on just-in-time production is another concerning element impeding industry expansion.
The COVID-19 epidemic has altered operational efficiency and disrupted value chains due to the rapid settlement of national and international borders, resulting in revenue loss and harm. According to Energy Industry Review research, the economic crisis accompanied by the pandemic may cause a significant delay in the development and commercialization of clean hydrogen energy. This may also have an impact on the hydrogen sector's ability to function smoothly as the missing link in the energy transition.
Aluminium bronze (AB5) segment is expected to hold largest share throughout the forecasted period. The AB5-type hydrogen storage alloy Mm (Ni, Mn, Co, Al) 5 is one of several alloy series that are currently widely utilized. The alloy MmNi3.55Mn0.4Al0.3Co0.75 was demonstrated to meet the basic requirements for a viable battery in terms of cost, cycle life, and storage capacity. AB5 alloys combine a hydride-forming metal A, typically a rare-earth metal (La, Ce, Nd, Pr, Y, or their mixture known as Mischmetal), with a non-hydride-forming element, nickel.
The aluminum bronze (AB2) segment is predicted to have the market's highest CAGR. As Ni-MH battery anodes, AB2 alloys have been widely researched. Because hydrogen diffusion inside the crystal lattice is the determining stage in the hydrating process, a comparison between the gas phase and the electrochemical environment was performed. Concerning structural changes caused by hydration, we discovered the segregation of various stable phases and variations in unit cell characteristics in each alloy.
North America is expected to have the largest market share. Rising demand for environmentally friendly technology in the automotive industry opens up new opportunities for a new player in the mobility sector, hydrogen, which is boosting the North American hydrogen storage alloys market. As a result, technological improvements and growth in the electronic industry are expected to drive demand for hydrogen storage alloys over the forecast period.
Because of the influence of productivity gains, the Asia-Pacific region is expected to have the highest CAGR in the market. The Asia-Pacific's growing economies are adopting varied foreign equipment, increasing manufacturing efficiency. This is backed by factors such as considerable government investments in emerging countries. However, these funds are intended to support large-scale infrastructure initiatives.
Some of the key players in Hydrogen Storage Alloys market include Baotou Santoku Battery Materials Co., Ltd., Ajax Tocco Magnethermic Corporation, Whole Win (Beijing) Materials Science and Technology Company, Japan Metals & Chemicals, Merck KGaA, Chuo Denki Kogyo, Guangdong Rising Nonferrous Metals Group, China Northern Rare Earth (Group) High-Tech, American Elements, Lab Tech, Mitsui , Jiangmen Kanhoo Industry Co. Ltd , AMG Titanium Alloys & Coatings LLC, Santoku Corporation, H Bank Technology, Xiamen Tungsten Co. Ltd and Liaoning Kingpowers Group.
In October 2019, AMG acquired titanium master alloys producer international specialty alloys. This acquisition of ISA provides an excellent opportunity for AMG to increase its market position in these key products for the aerospace market in North America and Europe.
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