市場調查報告書
商品編碼
1300148
自修復材料市場 - 2018-2028年全球行業規模、佔有率、趨勢、機會和預測,按形式、按材料類型、按最終用途、按地區和按競爭情況分類Self-Healing Materials Market - Global Industry Size, Share, Trends, Opportunity, and Forecast, 2018-2028F Segmented By Form,By Material Type By End Use, By Region and By Competition |
2022年,全球自修復材料市場的價值為15.3億美元,預計在預測期內將以9.16%的年複合成長率強勁成長,這是因為建築業的需求增加和政府的支持政策。
材料科學、奈米技術和聚合物化學的不斷發展,徹底改變了自修復材料的發展。新的癒合機制,如微膠囊、血管網路和可逆的化學鍵,擴大了自修復合材料的能力。這些機制使材料能夠檢測和應對損害,啟動恢復其完整性的癒合過程。受自然啟發的自修復材料模仿了生物系統和過程,利用了生物體內傷口癒合等概念。這些受生物啟發的材料具有獨特的癒合特性和更好的性能,推動了該領域的進一步研究和發展。
航空航太、汽車、電子和基礎設施等行業正擴大尋求表現出更高耐久性、可靠性和性能的材料。自修復材料為這些需求提供了引人注目的解決方案。自修復材料自主修復損壞的能力有助於延長產品的使用壽命,減少頻繁更換的需要和相關費用。自修復材料可以修復裂縫、划痕和其他結構性缺陷,最大限度地減少災難性故障的風險,提高關鍵應用的安全性。透過自主修復損壞,自修復材料減少了維護要求和相關費用,使其成為維護成本高的行業的有吸引力的選擇。
對自修復材料的研究和開發投資的增加推動市場的成長。製造商開發新的和創新的產品,以滿足各種最終用途的具體要求。各種終端行業,如汽車、運輸和電子行業,對先進的自修復聚合物的需求日益增加。自修復材料可以修復由機械摩擦造成的損壞,並在微觀層面上恢復功能,而不需要任何人工干涉。自修復材料可以幫助延長產品的使用壽命,降低維護成本。這對於停機時間可能很昂貴的行業,如汽車和航空航太業,非常重要。有利的政府貿易政策支持自我修復材料的成長和發展。支持擴大產品組合的尖端專業知識的實施,可能會擴大自修復材料的市場規模。
製造自修復材料往往包括複雜的流程和專業技術,導致生產成本提高。為確保廣泛採用,應努力最佳化生產方法,精簡製造程序,並利用規模經濟降低成本。
缺乏標準化的測試程序和品質控制協議給市場帶來了挑戰。自修復材料的可靠性和性能需要得到徹底的評估和驗證,以灌輸給終端用戶信心。建立全行業的標準、指南和認證計劃對於確保品質的一致性和促進市場接受度非常重要。
將自我修復機制整合到現有的材料和製造程序中是一個挑戰。工業通常有既定的材料和製造方法,這使得在不破壞現有操作的情況下涵蓋自我修復能力成為挑戰。材料科學家、工程師和製造商之間的合作對於製定無縫整合戰略非常重要,使自修復材料的採用不需要進行重大的流程改造。
雖然自修復材料表現出令人印象深刻的能力,但實現最佳的癒合效率和速度仍然是一個挑戰。癒合過程應該是快速、可靠的,並且能夠修復各種類型的損壞,包括裂縫、划痕和結構缺陷。研究工作應集中在加強癒合機制,開發更有效的癒合劑,並最佳化整個癒合過程,以盡量減少停機時間並提高性能。
確保自我修復材料的長期耐久性和有效性是另一個挑戰。這些材料必須在較長的時間內保持其癒合特性,抵制退化,並能承受惡劣的環境條件。長期測試和耐久性研究對於驗證自修復材料的性能和穩定性非常重要,為其長期可靠性提供信心。
日本Riken研究所的科學家們宣布,他們已經利用市面上的化合物開發出了第一種自修復合聚合物。據報導,自修復性聚合物是由現成的構建塊組成的。
北卡羅來納州立大學的工程研究人員宣布開發出一種新的自修復複合材料,可以在不使結構停用的情況下就地修復。這項最新技術解決了其在自修復材料方面的兩個長期挑戰,可以大大延長結構零件的壽命,如風力渦輪機葉片和飛機機翼。
2021年7月,英國研究創新部門的工程和物理科學研究委員會宣布了一項2250萬美元的合作,利用機器人干涉和自感應及自修復材料設計永續的道路維護工程。
2020年3月,固特異輪胎和橡膠公司發布了一款名為Recharge的新概念輪胎。這些輪胎可以有效地確定磨損程度,並在一種新的纖維增強的合成橡膠液體混合物的幫助下修復缺陷。
利用給定的市場資料,TechSci Research根據公司的具體需求提供客製化服務。本報告可提供以下客製化選項:
Global Self-Healing Materials market was valued at USD 1.53 billion in 2022 and is anticipated to project robust growth in the forecast period with a CAGR of 9.16%, owing to increasing demand from the construction industry and supportive government policies.
The materials science and engineering field has witnessed groundbreaking advancements in the development of self-healing materials. These remarkable materials possess the ability to autonomously repair the damage inflicted upon them, mimicking the regenerative capabilities found in living organisms. Self-healing materials have the potential to revolutionize numerous industries, including aerospace, automotive, electronics, and healthcare. Self-healing materials refer to a class of substances that possess the capability to repair damage, such as cracks, scratches, or structural flaws, without the need for external intervention. These materials can detect and respond to damage, initiating a repair process that restores their integrity and functionality. The key driving force behind self-healing materials is the incorporation of microcapsules, vascular networks, or reversible chemical bonds within the material's structure.
Self-healing materials represent a remarkable technological breakthrough with significant potential across various industries. From enhanced safety and durability in aerospace and automotive applications to improved reliability in electronics and advancements in healthcare, these materials have the power to reshape our world.
Self-healing polymers often contain tiny microcapsules filled with healing agents. When a crack or damage occurs, the capsule ruptures, releasing the healing agents into the damaged area. These agents then react with each other or with the material, forming a solid, polymerized bond that closes the crack.
Advances in nanotechnology and materials science will pave the way for the development of new healing mechanisms and materials. Integration of smart sensors and artificial intelligence will enable materials to detect and repair damage in real-time. Self-healing materials may contribute to the development of sustainable and circular manufacturing processes, by reducing waste and extending product lifecycles.
Global self-healing materials market has witnessed significant growth in recent years, driven by advancements in materials science, increasing demand for durable and sustainable materials, and expanding applications across various industries. Self-healing materials have the remarkable ability to autonomously repair damage, leading to improved performance, reduced maintenance costs, and extended product lifecycles. Global Self-healing Materials market has been experiencing steady growth, and its value is expected to reach billions of dollars in the coming years. The market growth can be attributed to several factors, including increasing investment in research and development, rising demand for advanced materials in key industries, and growing environmental concerns driving the need for sustainable solutions.
The continuous evolution of materials science, nanotechnology, and polymer chemistry has revolutionized the development of self-healing materials. New healing mechanisms, such as microcapsules, vascular networks, and reversible chemical bonds, have expanded the capabilities of self-healing materials. These mechanisms enable materials to detect and respond to damage, initiating a healing process that restores their integrity. Nature-inspired self-healing materials mimic biological systems and processes, leveraging concepts like wound healing in living organisms. These bioinspired materials offer unique healing properties and improved performance, driving further research and development in the field.
Industries such as aerospace, automotive, electronics, and infrastructure are increasingly seeking materials that exhibit enhanced durability, reliability, and performance. Self-healing materials offer a compelling solution to these demands. The ability of self-healing materials to autonomously repair damage helps extend the lifespan of products, reducing the need for frequent replacements and associated costs. Self-healing materials can repair cracks, scratches, and other structural flaws, minimizing the risk of catastrophic failures and enhancing safety in critical applications. By autonomously repairing damage, self-healing materials reduce maintenance requirements and associated expenses, making them an attractive choice for industries with high maintenance costs.
The increasing investments in research and development on self-healing materials are driving the growth of the market. Manufacturers are developing new and innovative products to meet the specific requirements of various end-use. The demand for advanced self-repairing polymers is increasing in various end-use industries, such as automotive, transportation, and electronics. Self-healing materials can repair damages caused by mechanical friction and restore functionalities at microscopic levels without any human intervention. Self-healing materials can help to extend the lifespan of products, which can lead to a reduction in maintenance costs. This is important in industries where downtime can be costly, such as the automotive and aerospace industries. Favorable governmental trade policies support the growth and development of self-healing materials. The implementation of sophisticated expertise that supports the expansion of the product portfolio is likely to expand the self-healing materials market size.
Manufacturing self-healing materials often involve complex processes and specialized technologies, resulting in higher production costs. To ensure widespread adoption, efforts should be directed toward optimizing production methods, streamlining manufacturing processes, and leveraging economies of scale to reduce costs.
The lack of standardized testing procedures and quality control protocols poses a challenge to the market. The reliability and performance of self-healing materials need to be thoroughly assessed and validated to instill confidence among end-users. Establishing industry-wide standards, guidelines, and certification programs will be crucial to ensure consistent quality and promote market acceptance.
Integrating self-healing mechanisms into existing materials and manufacturing processes presents a challenge. Industries often have established materials and manufacturing methods, making it challenging to incorporate self-healing capabilities without disrupting existing operations. Collaboration between material scientists, engineers, and manufacturers is essential to develop seamless integration strategies, enabling the adoption of self-healing materials without significant process overhauls.
While self-healing materials exhibit impressive capabilities, achieving optimal healing efficiency and speed remains a challenge. The healing process should be fast, reliable, and capable of repairing various types of damage, including cracks, scratches, and structural flaws. Research efforts should focus on enhancing healing mechanisms, developing more efficient healing agents, and optimizing the overall healing process to minimize downtime and improve performance.
Ensuring the long-term durability and effectiveness of self-healing materials is another challenge. The materials must maintain their healing properties over extended periods, resist degradation, and withstand harsh environmental conditions. Long-term testing and durability studies are essential to validate the performance and stability of self-healing materials, providing confidence in their long-term reliability.
Scientists at Japan's Riken Institute have announced they have developed the first self-healing polymer using commercially available compounds. Self-healing polymers are reportedly composed of readily available building blocks.
Engineering researchers at North Carolina State University have announced the development of a new self-healing composite that can repair structures in place without taking them out of service. This latest technology solves two of its longstanding challenges with self-healing materials and can significantly extend the life of structural components such as wind turbine blades and airplane wings.
In July 2021, the Engineering and Physical Sciences Research Council, a division of UK Research Innovation, announced a partnership for USD 22.5 million to design sustainable road maintenance projects using robotic interventions and self-sensing and self-healing materials.
In March 2020, Goodyear Tire and Rubber Company unveiled a new concept tire called Recharge. These tires can effectively determine the degree of wear and repair defects with the help of a new fiber-reinforced liquid mixture of synthetic rubber.
Global Self-Healing Materials market is segmented based on Form, Material Type, End-Use, Region, and Company. Based on Form, the self-healing materials market is further fragmented into Extrinsic and Intrinsic. Based on Material Type, the self-healing material market is fragmented into Polymer, Concrete, Coatings, and Others. Based on End Use, the self-healing materials market is divided into Building & Construction, Mobile Devices, Transportation, and Others. Based on Region, the self-healing material market is fragmented into Europe, North America, Asia Pacific, Middle East & Africa, and South America.
BASF SE, The Dow Chemicals Company, Wacker Chemie AG, Covestro AG, Huntsman International LLC, NEI Corporation, CompPair Technologies Ltd., Green-Basilisk BV, Autonomic Materials, Inc., Applied Thin Films Inc, Acciona S.A, Evonik Industries AG, Sensor Coating System Limited are some of the major players in the market.
In this report, Global Self-Healing Materials market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:
Company Profiles: Detailed analysis of the major companies present in Global Self-Healing Materials market.
With the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report: