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市場調査レポート
商品コード
1622689
スマートエレクトリックドライブ市場:地域別、2024年~2031年Smart Electric Drive Market By Component, Drive Type, Application, & Region for 2024-2031 |
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スマートエレクトリックドライブ市場:地域別、2024年~2031年 |
出版日: 2024年11月04日
発行: Verified Market Research
ページ情報: 英文 202 Pages
納期: 2~3営業日
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スマートエレクトリックドライブ市場の成長要因は、持続可能で効率的な輸送ソリューションに対する需要の高まりであり、これは世界の環境問題への懸念と厳しい排出規制によって後押しされています。政府のインセンティブや電気自動車インフラへの投資が市場成長を後押しする一方、顧客の嗜好は環境に優しく費用対効果の高いモビリティ・ソリューションへとシフトし、自家用車と商用車の両方でスマートエレクトリックドライブの使用を後押ししています。スマートエレクトリックドライブ市場は、2024年に12億4,349万米ドルの収益を突破し、2031年には106億2,053万米ドルに達すると推計されます。
バッテリー技術、パワーエレクトロニクス、通信開発のすべてが、スマートエレクトリックドライブ分野の大幅な進歩に貢献しています。リチウムイオン・バッテリーの強化やソリッド・ステート・バッテリーの開発により、エネルギー密度の向上、充電時間の短縮、航続距離の延長が実現しました。効率的なインバーターや回生ブレーキシステムなどのパワーエレクトロニクスの開発により、総合的な走行効率が向上しました。さらに、IoTとAIの組み合わせは、よりスマートなエネルギー管理、予知保全、スマートグリッドや家庭用エネルギーシステムへのシームレスな接続を提供します。スマートエレクトリックドライブ市場は、予測CAGR 35.90%で成長すると予想されます。
スマートエレクトリックドライブ市場定義/概要
スマートエレクトリックドライブは、電気モーター、バッテリー、制御エレクトロニクスを組み合わせ、性能、効率、運転の楽しさを向上させる高度な電気自動車(EV)推進システムです。このシステムは、インテリジェントなエネルギー管理、回生ブレーキ、さまざまな車両コンポーネントとのシームレスな統合を提供し、電気自動車の全体的な効率と航続距離を向上させることを目的としています。リアルタイムのデータ分析や通信などのスマート技術を使用するスマートエレクトリックドライブは、より優れた電力配分、バッテリー寿命の延長、ドライビング・ダイナミクスの向上を実現し、より持続可能で効率的な交通手段への移行における重要な要素となっています。電気自動車(EV)技術の開発、環境規制の強化、持続可能な輸送手段への世界のシフトにより、スマートエレクトリックドライブ(SED)の潜在的範囲は広大です。自動車メーカーの技術革新が進むにつれ、SEDシステムは、性能、安全性、ユーザー・エクスペリエンスを向上させるAI、IoT、スマート・バッテリー・マネジメント・システムなどの最先端技術を含め、より効率的になる可能性が高いです。
燃料価格の上昇に伴い、従来の内燃機関(ICE)車の運転コストが上昇しています。消費者は、運転コストの安い代替品を求めています。電気自動車(EV)、特にスマートエレクトリックドライブを搭載したEVは、エネルギー消費コストが低いです。EVの初期コストは高くつくかもしれないが、維持費や燃料費を含めた総所有コスト(TCO)は、ICE車と比較すると、一般的に長期にわたって低くなります。これは、燃料価格が上昇すればするほど、消費者にとって魅力的になります。
政府は、燃料価格の上昇を相殺し、よりクリーンな技術の採用を促進するために、電気自動車にインセンティブや補助金を提供することがあります。税額控除、還付金、登録料の減額などが考えられます。ガソリン価格の上昇は、効率的で費用対効果の高い電気モーターシステムの開発投資に拍車をかけるかもしれないです。バッテリー技術の進歩、航続距離の延長、総合性能の向上が起こるかもしれないです。気候変動や化石燃料が環境に与える影響に対する消費者の意識が高まり、より持続可能な交通手段を求めるようになっています。
さらに、電気自動車はテールパイプ排出がゼロであるため、より環境に配慮した選択肢となります。企業は、事業やサプライチェーンにおいて、企業の社会的責任を優先するようになってきています。ロジスティクスや輸送に電気自動車を利用することも含まれ、e-drive分野はさらに拡大すると思われます。消費者は、コネクティビティ、自律走行機能、スマートエネルギー管理システムなど、より現代的な機能を自動車に求めています。スマートエレクトリックドライブは、標準的な内燃エンジン自動車よりもシームレスにこれらの技術を組み合わせることができます。
さらに、回生ブレーキ、高速トルク、静音運転は運転体験を向上させ、電気自動車をより多くの人々にとって魅力的なものにします。より多くの自動車メーカーが電気自動車業界に参入するにつれて、競合によって技術革新が促進される一方、コストが低下します。これにより、スマートな電気自動車がより幅広い購買層で利用できるようになります。世界の電気自動車市場は、特に欧州、中国、北米で急速に拡大しています。これらの市場は、政府の強力な政策や、持続可能な交通手段に対する消費者の関心によって支えられていることが多いです。
CHAdeMO、CCS、テスラのスーパーチャージャーなど、メーカーによって異なるタイプの充電コネクターや規格を採用することが多いです。このような標準化の欠如は、適切な充電器が容易に入手できない可能性があるため、EV所有者に困難をもたらし、その結果、航続距離への不安や使用量の減少を招く可能性があります。車両と充電器の通信プロトコルに互換性がないと、非効率的な充電や充電不能を引き起こし、顧客体験を混乱させる可能性があります。
自律走行、ADAS(先進運転支援システム)、V2X(Vehicle-to-Everything)通信などの先進技術を組み合わせたスマート電気自動車のためのシームレスなソフトウェア統合を確保することは、これらのシステムが独自の技術を含むことが多いため困難です。自動車メーカー、ソフトウェア開発者、電力プロバイダーは、スマート電気駆動エコシステムの多くの利害関係者の一人です。複数のシステムやプラットフォーム間の相互運用性を実現するには、実質的な協力と標準化が必要です。
さらに、異なるスマート電気駆動システムやコンポーネントは、普遍的な互換性がない可能性があり、修理、メンテナンス、アップグレードを複雑にし、顧客のダウンタイムと費用を増加させる。複数のブランドやモデルを扱うために、サービス施設は様々な診断機器やソフトウェアにアクセスできなければならず、メンテナンスの複雑さとコストを増大させる。電気駆動装置の主要部品であるリチウムイオンバッテリーは、リチウム、コバルト、ニッケルなどの貴重な元素のために製造コストが高いです。
さらに、製造手順も複雑で高価です。技術開発と規模の経済によりコストは低下しているもの、内燃機関(ICE)車と比較すると依然として高いため、電気自動車(EV)の初期コストは高くなっています。自動運転車、強化されたセンサー、AIを活用した分析などのスマート技術の開発と統合には、多額の研究開発費が必要となります。安全性、信頼性、性能を確保するために、新しいスマート電気駆動技術の大規模なプロトタイピングとテストを実施すると、初期価格が上昇します。
電気駆動装置とスマート・コンポーネントの新しい生産ラインの確立、および既存の生産ラインの転換には多額の投資が必要です。自動化、精密工学、クリーンルーム設備への投資は、さらに出費を増やします。EVは一般的に、その耐用年数を通じて運用・保守費用が安く済むが、長期的なメリットよりも初期費用を優先する消費者にとっては、初期投資の大きさが障壁となる可能性があります。
The rising factor of the Smart Electric Drive market is driven by the increasing demand for sustainable and efficient transportation solutions, which is being fueled by global environmental concerns and tough emissions laws. Government incentives and investments in electric vehicle infrastructure help to drive market growth, while customer preferences shift toward eco-friendly and cost-effective mobility solutions, boosting the use of smart electric drives in both personal and commercial cars. The smart electric drive market is estimated to surpass a revenue of USD 1243.49 Million in 2024 and reachUSD 10620.53 Million by 2031.
Battery technology, power electronics, and communication developments have all contributed to substantial advancements in the Smart Electric Drive sector. Enhanced lithium-ion batteries and the development of solid-state batteries have resulted in higher energy density, shorter charging periods, and longer vehicle range. Power electronics developments, such as efficient inverters and regenerative braking systems, have increased total driving efficiency. Furthermore, the combination of IoT and AI offers smarter energy management, predictive maintenance, and seamless connectivity to smart grids and household energy systems. The smart electric drive market is expected to rise with a projected CAGR of 35.90 % from 2024 to 2031.
Smart Electric Drive Market: Definition/ Overview
Smart Electric Drive is an advanced electric vehicle (EV) propulsion system that combines an electric motor, battery, and control electronics to improve performance, efficiency, and driving pleasure. This system is intended to provide intelligent energy management, regenerative braking, and seamless integration with various vehicle components, hence increasing the overall efficiency and range of electric vehicles. Smart electric drives, which use smart technologies such as real-time data analysis and communication, provide better power distribution, longer battery life, and improved driving dynamics, making them an important component in the move to more sustainable and efficient transportation options. The potential scope of Smart Electric Drive (SED) is vast, owing to developments in electric vehicle (EV) technology, increased environmental restrictions, and a global shift toward sustainable transportation. As automakers continue to innovate, SED systems are likely to become more efficient, including cutting-edge technology like AI, IoT, and smart battery management systems to improve performance, safety, and user experience.
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As rising fuel prices, the cost of operating traditional internal combustion engines (ICE) vehicles increases. Consumers seek alternatives with cheaper operational costs. Electric vehicles (EVs), particularly those with smart electric drives, have lower energy consumption costs. While the initial cost of an EV may be greater, the total cost of ownership (TCO), which includes maintenance and fuel costs, is typically lower over time when compared to an ICE car. This becomes more appealing to consumers as fuel prices rise.
Governments may provide incentives or subsidies for electric vehicles to help offset growing fuel prices and stimulate the adoption of cleaner technology. Tax credits, refunds, and reduced registration fees may be included. Higher gasoline costs may spur investments in the development of efficient and cost-effective electric motor systems. Advancements in battery technology, higher vehicle range, and improved overall performance may ensue. Consumers are increasingly conscious of climate change and the environmental impact of fossil fuels, which is driving them to seek out more sustainable transportation solutions.
Furthermore, electric vehicles have zero tailpipe emissions, making them a more environmentally responsible choice. Companies are increasingly prioritizing corporate social responsibility in their operations and supply chains. The use of electric fleets for logistics and transportation is included, which would further increase the e-drive sector. Consumers desire more modern features in vehicles, such as connectivity, autonomous driving capabilities, and smart energy management systems. Smart electric drives can combine this technology more seamlessly than standard internal combustion engine automobiles.
Additionally, regenerative braking, fast torque, and silent operation improve the driving experience and make electric vehicles more appealing to a wider audience. As more automakers enter the electric vehicle industry, competition drives innovation while lowering costs. This makes smart electric vehicles more available to a broader audience of buyers. The global electric car market is increasing rapidly, particularly in Europe, China, and North America. These markets are frequently supported by strong government policies and consumer interest in sustainable transportation.
Different manufacturers frequently employ different types of charging connectors and standards, such as CHAdeMO, CCS, and Tesla's Supercharger. This lack of standardization can cause hardship for EV owners because appropriate chargers may not be readily available, resulting in range anxiety and decreased usage. Incompatibility in vehicle-to-charger communication protocols can cause inefficient charging or even inability to charge, disrupting the customer experience.
Ensuring seamless software integration for smart electric vehicles, which combine advanced technologies such as autonomous driving, ADAS (Advanced Driver Assistance Systems), and vehicle-to-everything (V2X) communication, is difficult because these systems frequently involve proprietary technologies. Car manufacturers, software developers, and electricity providers are among the many stakeholders in the smart electric drive ecosystem. Achieving interoperability between multiple systems and platforms necessitates substantial collaboration and standardization.
Furthermore, different smart electric drive systems and components may not be universally compatible, complicating repairs, maintenance, and upgrades, thus increasing downtime and expenses for customers. To handle multiple brands and models, service facilities must have access to a variety of diagnostic instruments and software, which increases the complexity and cost of maintenance. Lithium-ion batteries, a key component of electric drives, have high production costs due to valuable elements such as lithium, cobalt, and nickel.
Additionally, the manufacturing procedure is also complicated and expensive. While costs are reducing due to technological developments and economies of scale, they remain high as compared to internal combustion engine (ICE) vehicles, making electric vehicles (EVs) more expensive up front. Developing and integrating smart technologies such as self-driving cars, enhanced sensors, and AI-powered analytics necessitates significant R&D expenditure. Extensive prototyping and testing of new smart electric drive technologies to ensure safety, reliability, and performance increases the initial price.
Establishing new production lines for electric drives and smart components, as well as converting existing ones, requires significant investment. Investments in automation, precision engineering, and cleanroom facilities raise expenses even more. While EVs typically have cheaper operational and maintenance expenses over their lifespan, the larger initial investment may be a barrier for consumers who prioritize upfront costs over long-term benefits.
The increasing demand for battery-powered vehicles has hastened advances in battery technology, resulting in higher energy densities, faster charging times, and longer lifespans. These upgraded batteries boost the performance and appeal of smart electric vehicles, making them more appealing to consumers. Front-wheel drive (FWD) systems are simpler and less expensive to combine with smart electric drive components such as electric motors and control systems, which has accelerated the development and deployment of smart electric drives in FWD cars.
As the volume of battery-powered vehicles produced grows, economies of scale reduce the cost of batteries and related technology. This makes smart electric vehicles more inexpensive and accessible, hence fueling industry growth. FWD systems are less complex and cost less to construct than all-wheel or rear-wheel drive systems, making FWD electric cars (EVs) more economically viable. Smart electric drives enhance urban and compact vehicles because of their efficiency, compactness, and adaptability for city driving situations.
Furthermore, as more people realize the advantages of battery-powered and FWD vehicles, such as cheaper fuel costs, lower pollutants, and better driving experiences, their acceptance of smart electric drives grows. Many governments provide incentives and subsidies for battery-powered vehicles, especially those with front-wheel drive. These incentives reduce the purchase price and running costs, encouraging customers to select smart electric vehicles.
Additionally, stringent emission laws stimulate the use of battery-powered automobiles, which emit zero tailpipe emissions. FWD EVs, with their effective use of space and weight distribution, meet these legal standards, encouraging the development of smart electric drives. The desire to minimize carbon footprints and prevent climate change is driving the transition to battery-powered automobiles.
Companies are progressively adopting sustainable strategies, such as the shift to electric car fleets. FWD vehicles with smart electric motors are frequently chosen for their cost-effectiveness and environmental benefits, which help corporate sustainability goals. The rise of battery-powered automobiles has resulted in large investments in charging infrastructure. A well-developed charging network improves the practicality and ease of owning and operating smart electric vehicles, hence increasing market growth.
The increasing efficiency due to power electronics provided in the conversion and management of electrical energy, lowering losses and enhancing the overall efficiency of electric vehicles (EV). This development leads to higher performance and longer driving ranges, making EVs more appealing to consumers. Power electronics enable precise control of electric motors, which improves vehicle response, acceleration, and driving dynamics. This improvement increases EVs' competitiveness with regular internal combustion engine (ICE) vehicles.
Advances in power electronics enable the creation of more compact and integrated systems, reducing the size, weight, and cost of electric powertrains. This reduction may lower the production costs of EVs, making them more affordable to customers. Modern power electronics are built to be extremely dependable and long-lasting, able to tolerate harsh working conditions and extended operation.
Furthermore, effective thermal management solutions combined with power electronics enable peak performance and minimize overheating, increasing the lifespan and safety of electric drivetrains. Advanced regenerative braking systems powered by power electronics absorb energy while braking and feed it back into the battery, increasing energy efficiency and driving range. Intelligent charging solutions enabled by power electronics can improve charging times, save energy costs, and increase the convenience of owning an EV.
Additionally, AWD systems transmit power to all four wheels, resulting in improved traction and stability, particularly in severe weather or on difficult terrain. This increase improves safety and driving confidence, making electric vehicles more appealing to a wider spectrum of consumers. AWD improves EV performance and acceleration by more effectively distributing power, allowing EVs to compete with high-performance ICE vehicles. Offering AWD in EVs may attract customers who require or desire this function, such as those living in harsh winter climates or those interested in off-road capabilities.
Including AWD in EV products helps portray them as luxury or high-performance vehicles, luring buyers from these markets. Power electronics play an important part in regulating AWD systems by controlling power distribution between the wheels. This connection improves the performance and efficiency of AWD EVs. Combining AWD with other smart technologies, such as torque vectoring and adaptive suspension systems, can improve the driving dynamics and appeal of electric vehicles.
The increasing R&D spending promotes innovation in smart electric drive technology, including developments in electric motors, power electronics, battery management systems, and software integration to improve vehicle performance and efficiency. North America has a strong ecosystem of technology businesses, startups, research organizations, and universities working on EVs. Collaboration in this environment enhances scientific advancements in smart electric vehicles.
Investing in R&D helps North American corporations maintain technological leadership in autonomous driving, vehicle connection, and energy management. These improvements make smart electric drives more appealing and competitive around the world. Significant investments are being made to develop and improve EV charging infrastructure throughout North America. This involves the creation of fast-charging networks along highways, metropolitan centers, offices, and residential areas, which will alleviate range anxiety and improve convenience for EV owners.
Furthermore, smart electric drives enable V2G technologies, allowing EVs to return electricity to the grid during high demand periods. This feature enhances grid stability, facilitates renewable energy integration, and may reduce consumer costs. Government programs and policies encourage the development of EV charging infrastructure through subsidies, tax breaks, and regulatory changes. A well-developed R&D framework and infrastructure instills consumer trust in the dependability, performance, and convenience of smart electric drives, which is critical for speeding consumer adoption of advanced EV technologies.
Additionally, urbanization trends increase the demand for efficient, ecologically friendly transportation options. Smart electric drives, especially in FWD versions suitable for urban contexts, effectively meet these mobility requirements. The total cost of ownership for EVs, including those with smart electric drives, falls as technological advances and economies of scale are realized. Lower running costs, fewer maintenance requirements, and potential financial incentives make EVs more appealing to a wider spectrum of buyers.
Smart electric drives help to reduce greenhouse gas emissions and air pollutants, which aligns with North America's goals for climate change mitigation and better air quality. Regulatory support for zero-emission vehicles further encourages the use of smart electric drives. Smart electric drives play an important part in meeting these corporate social responsibility goals by providing efficient and ecologically friendly transportation options.
The rising urbanization in Asia-Pacific, with millions of people flocking to cities in quest for better economic prospects and living conditions. As people relocate to cities, population densities rise, as does need for sustainable, efficient, and environmentally friendly transportation options. Environmental issues such as air pollution, traffic congestion, and noise are significant obstacles for Asian cities. These concerns are prompting governments and urban planners to push cleaner modes of transportation, such as electric vehicles (EVs) outfitted with smart electric motor technologies.
The region's governments are implementing supportive policies to tackle urban pollution and cut greenhouse gas emissions. Subsidies, tax breaks, and exemptions from congestion charges are among the measures that encourage the adoption of electric vehicles. Infrastructure construction for EV charging is happening in cities to support the growing fleet of electric vehicles. This growth includes public charging stations, workplace charging facilities, and residential charging solutions.
Furthermore, improved charging infrastructure increases EV owners' convenience and range confidence, hence boosting market expansion. Asia-Pacific is a global automotive manufacturing hub, with substantial production facilities for automobiles and automotive components such as electric vehicles, batteries, electric motors, and power electronics, all of which are vital components of smart electric drives. The region's strong manufacturing skills allow economies of scale in electric vehicles and related components production.
Additionally, high scale production lowers manufacturing costs, making smart electric drives more affordable to consumers and enterprises. Proximity to manufacturing areas encourages innovation and technology developments in electric transportation across Asia-Pacific. Companies in the region are aggressively spending in R&D to improve battery efficiency, create innovative power electronics, and incorporate smart features into electric drivetrains. These developments enhance the performance, dependability, and market appeal of smart electric drives.
Asia-Pacific's comprehensive supply chain network enables the smooth sourcing of raw materials, components, and assembly processes required for electric vehicles. This integrated supply chain shortens lead times and increases production efficiency, addressing the growing demand for smart electric drives both domestically and globally.
The competitive landscape of the smart electric drive market is defined by a dynamic interaction of technological innovation, regulatory compliance, and market expansion plans. Emerging enterprises and startups are using breakthroughs in electric vehicle (EV) technology, such as smart electric drives, to carve out specialized markets and compete with established competitors. These newcomers frequently concentrate on niche applications like urban transportation solutions, business fleet electrification, and unique EV services. Partnerships and collaborations across industries further impact competitive dynamics, with the goal of integrating smart electric motors with advances in autonomous driving, connectivity, and sustainable energy solutions.
Some of the prominent players operating in the smart electric drive market include:
Nidec Corporation
Aisin Corporation
BorgWarner
Robert Bosch GmbH
ZF Friedrichshafen AG
Magna International Inc.
Continental AG
Hyundai Mobis
Schaeffler Group
In June 2024, ElectroRide, a multi-brand electric vehicles retail chain, has partnered with Battery Smart, to set up battery swapping stations across 2,500 locations across India, in the next five years. Initially, 50 stations will be set up in Delhi and Uttar Pradesh at ElectroRide locations. This partnership aims to simplify and enhance the adoption of electric mobility by providing convenient, economical, and efficient battery swapping services. The stations, strategically located to serve urban and intercity commuters, aim to reduce wait times with stations accessible within a 1 km radius.
In August 2023, Xpeng to Acquire Ride-Hailing Company DiDi's Smart EV Development Business. Xpeng, in partnership with Didi Global Inc., plans to launch a new EV brand in 2024 that is being developed under the project name "MONA". The new brand is targeted at the mass market segment at an expected price point of about Yuan 150,000. Xpeng and German auto giant Volkswagen signed a deal to develop two new EV cars for China under the VW brand but with Xpeng tech for software and autonomous driving. Targeting the middle-class segment.
In October 2023, Wallbox Announces Acquisition of ABL, a Leading EV Charging Provider in Europe. Wallbox's acquisition of ABL, with over 1 million EV chargers installed globally, accelerates its commercial strategy significantly. It expands Wallbox's product portfolio, enhances certification capabilities such as compliance with German EV charging laws, and leverages ABL's established relationships and experienced team. This acquisition reduces operational risks through decreased Capex and R&D spending while benefiting from ABL's manufacturing capabilities. Wallbox gains the ability to bring new products, like Supernova and Hypernova DC fast chargers, to market swiftly and efficiently.