市场调查报告书
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1401878
到 2030 年併网逆变器市场预测:按类型、额定功率输出功率、电压、应用、最终用户和地区进行的全球分析Grid-forming Inverter Market Forecasts to 2030 - Global Analysis By Type (Micro Inverter, Central Inverter, String Inverter, Hybrid-Inverters and Other Types), Output Power Rating, Voltage, Application, End User and By Geography |
根据 Stratistics MRC 的数据,2023 年全球併网逆变器市场规模为 6.8 亿美元,预计预测期内复合年增长率为 10.9%,到 2030 年将达到 14.029 亿美元。
併网逆变器需要将太阳能光伏发电、风能和水力发电等可再生能源整合到电力系统中。逆变器将这些零星能源来源与电网同步,进而提高系统稳定性。这些逆变器主动控制和调节电网电压和频率,是确保电力系统稳定性和可靠性的重要要素。逆变器有助于在发电波动或中断时稳定电网。
根据国际能源总署(IEA)统计,2020年以来,全球可再生能源发电容量扩大了60%以上,2026年将达到4,800(GW)以上,超过全球石化燃料和核能发电总容量的总和。预计可与
扩大可再生能源领域投资
推动併网逆变器市场的主要因素之一是可再生能源产业投资的增加。世界正在增加对太阳能光伏发电、风能和水力发电等可再生能源发电技术的投资,以实现更永续的能源未来。推动这些投资的因素有很多,包括应对气候变迁、减少温室气体排放和提高能源安全。併网逆变器对于再生能源来源整合到电力系统中至关重要。这使得再生能源来源能够在岛屿或微电网设置中工作,并有助于系统稳定性。
严格的电网规范和规定
电网规范是一组控制电网运作的规则。除了逆变器的通讯协定外,通常还有电能品质标准。电网规范因国家/地区而异,并且可能很复杂且难以遵循。一些国家在财政上鼓励安装併网逆变器,以减轻併网逆变器安装成本的负担,这阻碍了市场的成长。
能源储存整合需求
随着人们越来越关注整合能源储存来控制可再生能源波动和提高电网性能,对併网逆变器的需求不断增加。这些逆变器对于调节和监控能源储存设备、电网和再生能源来源的相互作用至关重要。由于併网逆变器,能源储存系统可以与太阳能光伏发电和风能等再生能源来源无缝整合。此外,逆变器可以更轻鬆地控制能源储存设备的充电和放电,从而最大限度地提高电网中能源储存设备的性能。
技术挑战
技术障碍可能会减缓併网逆变器技术的发明和进步速度。由于难以克服这些障碍,将新的、更先进的逆变器推向市场可能会被推迟。此外,技术解决方案不足可能会导致併网逆变器的效率降低、性能不佳或功能减少。这可能会影响整个系统的电压、频率和稳定性的控制能力,从而阻碍市场成长。
全球供应链因疫情而中断,影响了併网逆变器所需组件的生产和供应。逆变器供应受到生产放缓、原材料供应延迟和物流困难的影响。然而,儘管短暂停电,这次疫情的爆发还是引起了人们对能源弹性和再生能源来源重要性的关注。随着各国政府将重点转向永续性和经济復苏,他们越来越多地投资于可再生能源计划,包括併网逆变器。
微型逆变器领域预计将在预测期内成为最大的领域
微型逆变器提供的电池板级监控功能可让您准确追踪每个太阳能板的性能。这种粒度使得更容易快速检测单一面板中的问题和低效率,从而提高整体系统效率和维护。微型逆变器透过降低面板级的高直流电压来提高系统安全性,从而提高安装、维护和紧急情况下的安全性。分散式架构进一步增强系统冗余并促进市场成长。
风力发电场预计在预测期内复合年增长率最高
预计风力发电场领域在预测期内的复合年增长率最高。因为有併网逆变器的风力发电机可以调节和控制电力输出的电压和频率。此外,维持电网的稳定性和可靠性需要确保所产生的电力符合电网要求。风速的波动会导致风电的波动,因此併网逆变器可以透过改变输出功率以满足电网需求来帮助管理这些波动,并在风电波动的情况下保持电网稳定。我们将为您提供支援。
预计亚太地区在预测期内将占据最大的市场占有率。这是因为对併网逆变器的需求是由政府支持政策、奖励和计划强调亚太地区国家的电网稳定性和可再生能源部署。亚太国家经济的快速成长和能源消费量的增加需要创新的电网技术,例如併网逆变器,以有效满足不断增长的能源需求。此外,对电网基础设施现代化和更新的投资推动了电网逆变器技术的进步,特别是在新兴国家。
预计欧洲在预测期内将经历最高的复合年增长率,因为该国推动分散式能源发电系统将导致分散式再生能源来源取代集中式发电。併网逆变器透过提高分散式电网的稳定性来促进这一转变。在欧洲,由于对电网现代化和可再生能源整合的重视,併网逆变器的使用正在迅速增加。併网逆变器有助于再生能源来源的整合并实现电网的稳定性和弹性,已成为欧洲不断变化的能源格局的关键要素。
According to Stratistics MRC, the Global Grid-forming Inverter Market is accounted for $680.0 million in 2023 and is expected to reach 1,402.9 million by 2030 growing at a CAGR of 10.9% during the forecast period. In order to incorporate renewable energy sources like solar, wind, and hydroelectric power into the electrical system, grid-forming inverters are necessary. They make it possible for these sporadic energy sources to synchronize with the grid and increase system stability. The voltage and frequency of the grid, which are essential elements for guaranteeing the stability and dependability of the power system, may be actively controlled and regulated by these inverters. They support grid stabilization in the event of power generation variations or disruptions.
According to the International Energy Agency Worldwide renewable electricity capacity is predicted to expand by more than 60% from 2020 to over 4,800 (GW) by 2026, equaling the total global power capacity of fossil fuels and nuclear power combined.
Growing investment in the sector of renewable energy
One major factor propelling the grid-forming inverter market is the increase in investments in the renewable energy industry. The globe is investing a lot more in renewable power production technologies like solar, wind, and hydropower as it moves toward a more sustainable energy future. Numerous considerations, such as the need to battle climate change, lower greenhouse gas emissions, and improve energy security, are driving these investments. In order to incorporate renewable energy sources into the electrical system, grid-forming inverters are essential. This makes it possible for renewable energy sources to function in islanded or microgrid setups and contribute to system stability.
Stringent grid codes and regulations
Grid codes are a set of rules that control how the grid functions. Usually, they outline the standards for the power quality that must be produced in addition to the inverters' communication protocols. Country-to-country variations exist in grid codes, which can be complicated and hard to follow. Grid-forming inverter deployment is encouraged financially in some nations additionally to helping to defray the cost of installing grid-forming inverters, which hamper the growth of the market.
Demand for energy storage integration
Grid-forming inverters are becoming more and more necessary as the focus on integrating energy storage to control renewable energy fluctuation and improve grid performance grows. These inverters are essential for regulating and monitoring how energy storage devices, the grid, and renewable energy sources interact. Energy storage systems and renewable energy sources, such solar and wind power, may be seamlessly integrated thanks to grid-forming inverters. Moreover, they maximize energy storage units' performance inside the grid by making it easier for them to be charged and discharged under control which creates propelling opportunities for the market growth.
Technological challenges
The rate of invention and advancement in grid-forming inverter technology can be slowed down by technological obstacles. The release of new, more sophisticated inverters onto the market might be slowed delayed by difficulties in overcoming these obstacles. Moreover, the Inadequate technological solutions might result in grid-forming inverters that are less effective, perform worse, or have less capabilities. This may affect how well they control the voltage, frequency, and stability of the grid as a whole thus impeding the growth of the market.
Global supply chains were disrupted by the epidemic, which had an impact on the production and availability of parts needed for grid-forming inverters. The supply of inverters was impacted by production slowdowns, delays in obtaining raw materials, and logistical difficulties. However, the epidemic brought attention to the significance of energy resiliency and renewable energy sources, despite brief outages. Investments in renewable energy projects including those with grid-forming inverters became more and more popular as governments shifted their attention to sustainability and economic recovery.
The micro inverter segment is expected to be the largest during the forecast period
The micro inverter segment is estimated to have a lucrative growth; due to the panel-level monitoring features offered by microinverters, it is possible to precisely track each solar panel's performance. This granularity facilitates the prompt detection of problems or inefficiencies in individual panels, hence enhancing the overall efficiency and maintenance of the system. By lowering high DC voltages at the panel level and boosting safety during installation, maintenance, and emergency situations, microinverters increase system safety. Their decentralized architecture further strengthens the system's redundancy thus boosting the growth of the market.
The wind power plants segment is expected to have the highest CAGR during the forecast period
The wind power plants segment is anticipated to witness the highest CAGR growth during the forecast period, because wind turbines with grid-forming inverters may regulate and control the electrical output's voltage and frequency. Additionally, maintaining grid stability and dependability requires making sure that the generated electricity meets the grid's requirements. Variations in wind speed can lead to variations in wind power generation thereby by modifying the output power to fit the grids demand and preserve grid stability even during changes in wind energy production, grid-forming inverters assist in managing these variances.
Asia Pacific is projected to hold the largest market share during the forecast period due to the demand for grid-forming inverters is being driven by supportive government policies, incentives, and programs that emphasize grid stability and the deployment of renewable energy in nations around the Asia Pacific region. In order to effectively fulfil the expanding energy requirements, innovative grid technologies such as grid-forming inverters are becoming more necessary in Asia Pacific countries because to their rapid economic expansion and rising energy consumption. Moreover, advances in grid-forming inverter technology are being made possible by investments in modernizing and updating grid infrastructure, especially in emerging nations.
Europe is projected to have the highest CAGR over the forecast period, owing to distributed renewable energy sources which will replace centralized power generation as part of Europe's push toward decentralized energy systems. Grid-forming inverters promote the stability of decentralized power networks, which makes this transition easier. Europe's growing emphasis on grid modernization and the integration of renewable energy sources has led to a surge in the use of grid-forming inverters. Grid-forming inverters, which facilitate the integration of renewable energy sources and enable grid stability and resilience, are becoming crucial parts of Europe's changing energy environment.
Some of the key players profiled in the Grid-forming Inverter Market include Power Electronics, TBEA Xingjiang Sunoasis, Growatt New Energy, Huawei Technologies Co. Ltd., General Electric, SMA Solar Technology, Schneider Electric, SolarEdge Technologies, Delta Electronics, Altenergy Power System, Sensata Technologies, Delphi Technologies, KACO New Energy, TMEIC, Fronius International, Goodwe, Enphase Energy, Games Electric, SunPower Corporation and Canadian Solar In
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