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市场调查报告书
商品编码
1700095
2032 年汽车微型马达市场预测:按产品类型、功耗、车辆类型、销售管道、应用和地区进行的全球分析Automotive Micromotor Market Forecasts to 2032 - Global Analysis By Product Type (AC Micromotors and DC Micromotors), Power Consumption (Below 11V, 12V-24V, 25V-48V and Above 48V), Vehicle Type, Sales Channel, Application and By Geography |
根据 Stratistics MRC 的数据,全球汽车微型马达市场预计在 2025 年达到 193 亿美元,到 2032 年将达到 394 亿美元,预测期内的复合年增长率为 10.7%。
汽车中的小型机械系统由汽车马达驱动,这种马达是一种高精度、紧凑型马达。透过为电子油门控制、门锁、后视镜、电动座椅和通风系统等设备提供动力,这些马达提高了自动化程度、效率和舒适度。它们在低电压下运行,提供强度、扭矩和能源效率,使其成为现代汽车设计必不可少的。
根据ACEA预测,2024年全球汽车产量将达7,550万辆。
汽车电气化程度不断提高
汽车电气化程度的提升是汽车马达市场发展的关键驱动力。随着电动车窗和座椅等越来越多的部件实现电气化,对马达的需求也不断增长。此外,向电动车(EV)的转变正在加速这一趋势。电动车需要马达来实现各种自动化功能。此外,人们对豪华和技术先进的汽车的日益偏好也增加了对此类马达的需求。预计电气化趋势将持续下去,推动市场成长。
先进技术和材料高成本
这些马达的开发和生产需要在研发、製造和品管方面投入大量资金。此外,专用材料和现代製造方法的使用增加了生产成本,阻碍了新进入者,从而限制了市场竞争。这种财务障碍阻碍了创新和满足不断变化的客户需求的能力。
智慧网联网汽车的发展
自动驾驶技术和物联网系统需要用于感测器、自动后视镜和可调节座椅的马达。此外,豪华车辆越来越多地配备手势控制介面等可自订功能,这推动了对高精度马达的需求。汽车製造商和高科技公司朝着开发下一代行动解决方案的方向发展可能会进一步推动创新。此外,现有车辆的连接功能售后升级代表尚未开发的潜力,为製造商创造了新的收益来源。
不断变化的监管标准
不断变化的排放气体、安全和能源效率法律规范带来了挑战。遵守各种区域标准(例如欧 7 和中国电动车法规)将增加研发和生产成本。此外,突然的政策转变可能会扰乱供应链并延迟产品发布。例如,随着电动车噪音法规变得越来越严格,马达需要变得更安静,因此需要重新设计。监管的不确定性也会阻碍长期投资,特别是中小企业的投资,并威胁市场稳定。
COVID-19 疫情扰乱了全球供应链,导致製造业停顿,并影响了汽车马达市场。生产和分销受到严重影响,导致需求下降。然而,疫情后的復苏是由响应不断变化的市场需求的技术进步和创新所推动的。这支持了市场復苏和成长。
预计在预测期内,直流微马达市场将成长至最大的份额。
预计直流微马达将在预测期内占据最大的市场占有率,这得益于其可靠性、成本效益以及在挡风玻璃雨刷和燃油泵等传统汽车系统中的广泛应用。 12V-48V架构相容于现有车辆电气系统,确保稳定的需求。此外,向电动车的转变也使电池冷却和充电机制的作用越来越大。以中国和印度为首的亚太地区汽车製造业蓬勃发展,正在推动大规模生产并巩固主导。
预计预测期内 48V+ 部分将以最高的复合年增长率成长。
预计 48V 及以上领域将在预测期内见证最高成长率,这得益于电动车对高功率应用的需求,例如电动动力传动系统和快速充电系统。这些马达更加节能,产生的热量更少,这对于延长电池寿命至关重要。此外,豪华电动车和高性能汽车优先考虑 48V+ 系统,以实现主动悬吊和扭力向量等高级功能。特斯拉和宝马等汽车製造商正在整合高压架构,推动需求。监管部门推动更快的充电基础设施可能会进一步加速采用,使这一领域成为创新的焦点。
预计亚太地区将在预测期内占据最大的市场占有率。这一优势得益于电动车产业的蓬勃发展,尤其是在中国和印度,这两个国家对更清洁交通的监管支持正在推动对马达的需求。具有成本效益的劳动力和靠近原材料供应商的优势使得马达生产具有竞争力。此外,该地区强大的製造业基础和良好的经济状况支持马达的生产和应用。
预计亚太地区在预测期内的复合年增长率最高。该地区快速的工业化和都市化正在推动汽车持有和先进汽车技术需求的成长。此外,政府推广电动车的倡议和更严格的排放法规正在推动高效微型马达的采用。此外,该地区的竞争格局和创新生态系统正在推动技术进步和市场成长。
According to Stratistics MRC, the Global Automotive Micromotor Market is accounted for $19.3 billion in 2025 and is expected to reach $39.4 billion by 2032 growing at a CAGR of 10.7% during the forecast period. Small mechanical systems in cars are driven by automobile micromotors, which are high-precision, compact electric motors. By supplying power to devices like electronic throttle control, door locks, mirrors, power seats, and ventilation systems, these motors improve automation, efficiency, and comfort. They are vital to contemporary car designs since they run on low voltage and provide strength, torque, and energy efficiency.
According to ACEA, global car production reached 75.5 million units in 2024.
Growing electrification of vehicles
The increasing electrification of vehicles is a significant driver for the automotive micromotor market. As more components become electric, such as power windows and seats, the demand for micromotors grows. Furthermore, the shift towards electric vehicles (EVs) accelerates this trend, as EVs require micromotors for various automated functions. Additionally, the rising preference for luxury and technologically advanced vehicles enhances the need for these motors. This electrification trend is expected to continue, fueling market growth.
High cost of advanced technologies and materials
The development and production of these motors require significant investment in research and development, manufacturing, and quality control. Moreover, the use of specialized materials and modern manufacturing methods increases production costs, deterring new entrants and limiting market competition. This financial barrier hinders innovation and the ability to meet evolving customer demands.
Development of smart and connected vehicles
Autonomous driving technologies and IoT-enabled systems require micromotors for sensors, automated mirrors, and adjustable seating. Furthermore, luxury vehicles increasingly integrate customizable features, such as gesture-controlled interfaces, driving demand for high-precision micromotors. Collaborations between automotive and tech firms to develop next-gen mobility solutions will further propel innovation. Additionally, aftermarket upgrades for connectivity features in existing vehicles offer untapped potential, creating new revenue streams for manufacturers.
Changes in regulatory standards
Evolving regulatory frameworks on emissions, safety, and energy efficiency pose challenges. Compliance with diverse regional standards, such as Euro 7 or China's EV mandates, increases R&D and production costs. Moreover, sudden policy shifts can disrupt supply chains, delaying product launches. For instance, stricter noise regulations for EVs necessitate quieter micromotors, requiring redesigns. Uncertainty in regulations also discourages long-term investments, particularly for smaller players, threatening market stability.
The COVID-19 pandemic disrupted global supply chains and halted manufacturing, impacting the automotive micromotor market. Production and distribution were severely affected, leading to decreased demand. However, post-pandemic recovery has been driven by technological advancements and innovations that align with changing market needs. This has supported the market's rebound and growth.
The DC micromotors segment is expected to be the largest during the forecast period
The DC micromotors segment is expected to account for the largest market share during the forecast period, due to their reliability, cost-effectiveness, and widespread use in conventional automotive systems like windshield wipers and fuel pumps. Their compatibility with 12V-48V architectures aligns with existing vehicle electrical systems, ensuring steady demand. Furthermore, the transition to EVs has expanded their role in battery cooling and charging mechanisms. Asia Pacific's robust automotive manufacturing sector, led by China and India, drives volume production, solidifying this segment's leadership.
The Above 48V segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the above 48V segment is predicted to witness the highest growth rate, fueled by the need for high-power applications in EVs, such as electric powertrains and fast-charging systems. These motors enhance energy efficiency and reduce heat generation, critical for extending battery life. Moreover, luxury EVs and performance vehicles prioritize 48V+ systems for advanced features like active suspension and torque vectoring. Automakers like Tesla and BMW are integrating high-voltage architectures, propelling demand. Regulatory pushes for faster charging infrastructure will further accelerate adoption, making this segment a focal point for innovation.
During the forecast period, the Asia Pacific region is expected to hold the largest market share. This dominance is driven by the booming electric vehicle industry, particularly in China and India, where regulatory support for cleaner transportation fuels demand for micromotors. Cost-effective labor and proximity to raw material suppliers enable competitive micromotor production. Furthermore, the region's strong manufacturing base and favorable economic conditions support the production and adoption of micromotors.
Over the forecast period, the Asia Pacific region is anticipated to exhibit the highest CAGR. The region's rapid industrialization and urbanization lead to increased vehicle ownership and demand for advanced automotive technologies. Moreover, government initiatives promoting electric vehicles and stricter emission standards encourage the adoption of efficient micromotors. Additionally, the region's competitive manufacturing landscape and innovative ecosystem drive technological advancements and market growth.
Key players in the market
Some of the key players in Automotive Micromotor Market Market include Nidec Corporation, Johnson Electric Holdings Limited, Mitsuba Corporation, Buhler Motor GmbH, Constar Micromotor Co., Ltd., Mabuchi Motor Co., Ltd., Maxon Group, Wellings Holdings Ltd., Assun Motor, Denso Corporation, ABB Ltd., Siemens AG, Faulhaber Group, Portescap, AMETEK, Inc., Allied Motion Technologies Inc., Canon Inc. and MinebeaMitsumi Inc.
In January 2025, Starting in January the company will operate under the name FAULHABER Nordic ApS in Norway, Sweden, and Finland. The head office will be located in Allerod, Denmark, just north of Copenhagen, where FAULHABER has been active since mid-2024.
In March 2024, Siemens AG has signed an agreement to acquire the industrial drive technology (IDT) business of ebm-papst. The business, which employs around 650 people, includes intelligent, integrated mechatronic systems in the protective extra-low voltage range and innovative motion control systems. These systems are used in free-range driverless transport systems. The planned acquisition will complement the Siemens Xcelerator portfolio and strengthen Siemens' position as a leading solutions provider for flexible production automation.
In May 2023, DENSO CORPORATION (DENSO), a leading mobility supplier, and United Semiconductor Japan Co., Ltd. ("USJC"), a subsidiary of global semiconductor foundry United Microelectronics Corporation announced a joint collaboration to produce insulated gate bipolar transistors (IGBT), which have entered mass production at the 300mm fab of USJC. A first shipment ceremony was held today to mark this important milestone. It comes just one year after the companies announced a strategic partnership for this critical power semiconductor used in electric vehicles.
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.