市场调查报告书
商品编码
1541315
2024-2032 年按类型(光聚合物、ABS 和 ASA、聚酰胺/尼龙、聚乳酸等)、形式、应用、最终用户和地区分類的 3D 列印塑胶市场报告3D Printing Plastics Market Report by Type (Photopolymers, ABS and ASA, Polyamide/Nylon, Polylactic Acid, and Others), Form, Application, End User, and Region 2024-2032 |
IMARC Group年全球3D列印塑胶市场规模达12.41亿美元。永续和环保生产的不断增加、工具和模具製造应用的增加、按需生产潜力的不断增长、设计迭代和优化的改进以及增材製造服务的扩展是推动市场的一些因素。
三维 (3D) 列印塑胶涉及积层製造工艺,该工艺利用各种材料进行产品製造,包括丙烯腈丁二烯苯乙烯 (ABS) 长丝、热塑性塑胶、光聚合物和聚酰胺。这些材料通常由源自天然来源和石化产品的半合成和合成化合物组成。由此产生的 3D 列印塑胶具有轻质、柔韧、易于灭菌、生物相容性以及改进的化学、热和机械特性等品质。除了这些特征之外,该流程还有助于快速高效的设计迭代或变更,从而简化专案的大规模客製化并允许组装整合。利用这些属性,3D 列印塑胶在各个领域都有应用,可以原型设计、修改和製造不同形状、尺寸和强度的工具、组件和配件。目前,这些塑胶有长丝、粉末、液体和墨水形式,在不同的製造技术中提供了灵活性。
全球市场主要受到3D列印技术快速进步的推动。与此一致的是,各行业中不断增加的应用和材料创新正在为市场做出巨大贡献。此外,不断增长的客製化和个人化需求以及缩短的产品开发週期正在对市场产生积极影响。除此之外,材料浪费的减少和快速原型製作的日益使用正在催化市场。此外,航空航太和汽车领域的不断扩大的采用以及医疗和保健行业的利用不断升级正在推动市场的发展。此外,复杂几何形状的製造能力和具有成本效益的小规模生产正在增强市场。此外,3D 列印设备的普及以及消费品和电子产品製造的不断增长也推动了市场的发展。
提高人们对 3D 列印塑胶优点的认识
人们对 3D 列印塑胶优势的认识不断增强,为市场创造了积极的前景。随着业界和消费者越来越了解该技术的功能,他们对采用 3D 列印塑胶进行各种应用的兴趣也随之增强。对设计灵活性、客製化、快速原型製作和减少材料浪费等属性的认识促使更多企业和个人探索 3D 列印塑胶并将其整合到他们的流程中。这种加深的理解会产生连锁效应,刺激对研究、开发和设备的投资,并鼓励产业之间的合作,以利用这种创新製造方法的潜力。随着意识的传播,3D 列印塑胶市场正在不断扩大,刺激创新并为持续成长奠定坚实的基础。
汽车产业对 3D 列印塑胶的采用不断增加
汽车产业越来越多地采用 3D 列印塑料,这标誌着塑造产业格局的重大趋势。汽车製造商正在转向 3D 列印塑胶来彻底改变从原型设计到最终零件生产的各种操作。这种采用是由该技术快速创建复杂几何形状、减少材料浪费和加快产品开发週期的能力所推动的。这些塑胶使汽车工程师能够更有效地製作原型和测试组件,从而加快设计迭代并提高车辆的整体性能。此外,3D 列印中塑胶的轻量化特性符合汽车产业对轻质材料的推动,以提高燃油效率并减少排放。除了原型製作之外,3D 列印塑胶也越来越多地用于製造最终用途组件,例如内饰板、支架和引擎零件。这允许按需生产和定制,简化供应链并减少对大量仓储的需求。 3D 列印塑胶在汽车领域的日益整合提高了营运效率并推动了创新,使製造商能够突破设计和功能的界限。随着这一趋势的持续发展,它将重塑传统汽车製造,强调敏捷性、永续性和前沿的设计概念。
与工业 4.0 和数位化製造集成
将 3D 列印塑胶与工业 4.0 和数位製造相结合,促进了生产方法的典范转移。这些技术的融合使製造过程更加互联、自动化和高效。工业 4.0 原则倡导智慧、数据驱动的系统,以实现即时监控和控制。透过将 3D 列印塑胶纳入该框架,公司可以按需生产组件,从而降低库存成本并最大限度地缩短交货时间。设计的数位化可以实现快速调整和迭代,从而提高响应市场需求的敏捷性。此外,3D 列印塑胶与工业 4.0 的结合可促进预测性维护。感测器可以监控 3D 列印机的性能并在问题出现之前进行干预,确保生产的一致性和不间断性。数位製造受益于 3D 列印塑胶能够创建复杂的设计,而这些设计曾经对传统製造来说是一项挑战。这种协同作用可以精确地生产复杂的客製化零件。
The global 3D printing plastics market size reached US$ 1,241 Million in 2023. Looking forward, IMARC Group expects the market to reach US$ 6,738 Million by 2032, exhibiting a growth rate (CAGR) of 20.4% during 2024-2032. The increasing sustainable and eco-friendly production, the rising tooling and mold manufacturing applications, the growing potential for on-demand production, the improved design iteration and optimization, and the expansion of additive manufacturing services are some of the factors propelling the market.
Three-dimensional (3D) printing plastics involve an additive manufacturing process that utilizes various materials, including acrylonitrile butadiene styrene (ABS) filaments, thermoplastics, photopolymers, and Polyamide, for product fabrication. These materials typically consist of semi-synthetic and synthetic compounds derived from natural sources and petrochemicals. The resulting 3D-printed plastics exhibit qualities such as lightweightness, flexibility, easy sterilization, biocompatibility, and improved chemical, thermal, and mechanical attributes. Beyond these characteristics, the procedure facilitates swift and efficient design iterations or alterations, enabling streamlined mass customization of items and allowing for assembly consolidation. Capitalizing on these attributes, 3D printing plastics find applications across various sectors to prototype, modify, and manufacture tools, components, and accessories of varying shapes, sizes, and strengths. Currently, these plastics are available in filaments, powders, liquids, and inks, offering flexibility across different manufacturing techniques.
The global market is majorly driven by the rapid advancements in 3D printing technology. In line with this, the increasing applications in various industries and material innovations are significantly contributing to the market. Furthermore, the rising customization and personalization demand and the shortened product development cycles are positively influencing the market. Apart from this, the reduced material wastage and the growing use of rapid prototyping are catalyzing the market. Moreover, the expanding adoption in the aerospace and automotive sectors and the escalating medical and healthcare industry utilization are propelling the market. Besides, the complex geometries manufacturing capability and the cost-effective small-scale production are strengthening the market. Additionally, the accessibility of 3D printing equipment and the increasing consumer goods and electronics manufacturing is providing a boost to the market.
Increasing awareness regarding the benefits of 3D printing plastics
The increasing awareness of the benefits of 3D printing plastics creates a positive outlook for the market. As industries and consumers become more informed about the capabilities of this technology, their interest in adopting 3D printing plastics for diverse applications intensifies. The awareness of attributes like design flexibility, customization, rapid prototyping, and reduced material waste propels more businesses and individuals to explore and integrate 3D printing plastics into their processes. This heightened understanding has a cascading effect, spurring investments in research, development, and equipment and encouraging collaborations between industries to harness the potential of this innovative manufacturing approach. As awareness spreads, the 3D printing plastics market is propelled towards expansion, stimulating innovation and establishing a solid foundation for sustained growth.
Rising uptake of 3D printing plastics in the automotive sector
The increasing adoption of 3D printing plastics within the automotive sector signifies a significant trend shaping the industry's landscape. Automotive manufacturers are turning to 3D printing plastics to revolutionize various operations, from prototyping to final part production. This uptake is driven by the technology's ability to swiftly create complex geometries, reduce material wastage, and expedite the product development cycle. These plastics enable automotive engineers to prototype and test components more efficiently, leading to faster design iterations and improved overall vehicle performance. Moreover, the lightweight nature of plastics in 3D printing aligns with the automotive industry's push for lightweight materials to enhance fuel efficiency and reduce emissions. Beyond prototyping, 3D printing plastics are increasingly used to manufacture end-use components, such as interior panels, brackets, and engine parts. This allows for on-demand production and customization, streamlining supply chains and reducing the need for extensive warehousing. The rising integration of 3D printing plastics in the automotive sector boosts operational efficiency and fuels innovation, enabling manufacturers to push the boundaries of design and functionality. As this trend continues, it's poised to reshape traditional automotive manufacturing, emphasizing agility, sustainability, and cutting-edge design concepts.
Integration with Industry 4.0 and digital manufacturing
Integrating 3D printing plastics with Industry 4.0 and digital manufacturing catalyzes a paradigm shift in production methodologies. Blending these technologies makes manufacturing processes more connected, automated, and efficient. Industry 4.0 principles advocate for smart, data-driven systems that enable real-time monitoring and control. By incorporating 3D printing plastics into this framework, companies can produce components on-demand, reducing inventory costs and minimizing lead times. The digitization of designs enables quick adjustments and iterations, fostering agility in responding to market demands. Furthermore, combining 3D printing plastics and Industry 4.0 promotes predictive maintenance. Sensors can monitor the performance of 3D printers and intervene before issues arise, ensuring consistent and uninterrupted production. Digital manufacturing benefits from 3D printing plastics' ability to create intricate designs that were once challenging to manufacture conventionally. This synergy allows for the production of complex, customized parts with precision.
IMARC Group provides an analysis of the key trends in each segment of the global 3D printing plastics market report, along with forecasts at the global, regional and country levels from 2024-2032. Our report has categorized the market based on type, form, application and end user.
Photopolymers
ABS and ASA
Polyamide/Nylon
Polylactic Acid (PLA)
Others
Photopolymers dominates the market
The report has provided a detailed breakup and analysis of the market based on the type. This includes photopolymers, ABS and ASA, polyamide/nylon, polylactic acid (PLA), and others. According to the report, photopolymers represented the largest segment.
Photopolymers stand out for their ability to rapidly solidify under light exposure, making them well-suited for intricate designs and fine details. Their applications span industries such as dentistry, jewelry, and consumer goods. The growth of photopolymer utilization is driven by increasing demand for highly detailed, visually appealing prototypes and end-use products.
Furthermore, ABS and ASA offer durability, strength, and thermal resistance, making them ideal for functional prototypes and parts. These materials find extensive use in industries like automotive, aerospace, and electronics. The growth in demand for sturdy, reliable components drives the expansion of ABS and ASA in the 3D printing plastics market.
Moreover, Polyamide or nylon materials excel in providing mechanical strength, flexibility, and chemical resistance. They find applications in industrial and consumer sectors, including manufacturing jigs, fixtures, and wear-resistant components. The growth in utilization of polyamide/nylon is attributed to these materials' versatility and wide-ranging applications.
The strategic emphasis on these distinct 3D printing plastics reflects their increasing adoption across diverse industries. This targeted approach addresses market needs and encourages innovation, research, and material development. As each type of 3D printing plastic finds its niche and contributes to different sectors, the overall market gains momentum, supported by an ecosystem of specialized materials that cater to evolving industry demands.
Filament
Liquid/Ink
Powder
Filament dominates the market
The report has provided a detailed breakup and analysis of the market based on the form. This includes filament, liquid/ink, and powder. According to the report, filament represented the largest segment.
Filament-based 3D printing is popular due to its accessibility and compatibility with various 3D printers. This form is widely used for prototyping, DIY projects, and small-scale production. The growth in filament adoption is driven by its user-friendly nature and versatility.
Furthermore, liquid or ink-based 3D printing, or stereolithography (SLA), utilizes photosensitive polymers that solidify when exposed to light. This form is prized for its ability to produce highly detailed, intricate designs with smooth surfaces. The growth in liquid/ink 3D printing is fueled by applications in jewelry, dental, and art-related sectors that demand precision and aesthetics.
Moreover, powder-based 3D printing, including selective laser sintering (SLS), involves fusing layers of powdered material using a laser. This form is well-suited for producing complex geometries and functional parts with various materials, including metals. The growth in powder-based 3D printing is driven by its ability to create strong, durable parts and its applications in industries like aerospace and medicine.
The segmentation by form caters to different user preferences and industrial requirements, expanding the potential applications of 3D printing plastics. As each form addresses specific needs and opens up unique opportunities, the market gains momentum from a diverse ecosystem of 3D printing technologies that collectively contribute to the growth and advancement of the industry.
Manufacturing
Prototyping
Prototyping dominates the market
The report has provided a detailed breakup and analysis of the market based on the application. This includes manufacturing and prototyping. According to the report, Prototyping represented the largest segment.
These plastics have long been utilized for rapid prototyping, enabling engineers and designers to create physical models of products for testing and validation quickly. This application accelerates design iterations and reduces development time, making it a cornerstone of the product development cycle across electronics, medical devices, and fashion industries.
On the other hand, the use of 3D printing plastics in manufacturing processes is gaining traction due to its ability to produce end-use components directly. Industries such as aerospace, automotive, and consumer goods increasingly integrate 3D printing plastics into their production lines to create functional parts with complex geometries and reduced material wastage. This application enables agile production, customization, and even on-demand manufacturing.
Automotive
Healthcare
Aerospace and Defense
Consumer Goods
The report has provided a detailed breakup and analysis of the market based on the end user. This includes automotive, healthcare, aerospace and defense, and consumer goods.
The automotive sector is a major adopter of 3D printing plastics, utilizing the technology for rapid prototyping, tooling, and manufacturing lightweight components. The automotive industry benefits from the ability to create customized parts, improve design iterations, and reduce production lead times. 3D printing plastics find applications in producing interior components, engine parts, and even entire vehicle prototypes, contributing to innovation and efficiency within the automotive manufacturing process.
Furthermore, 3D printing plastics are revolutionizing medical device manufacturing and patient-specific solutions in the healthcare sector. From creating anatomical models for surgical planning to developing custom implants and prosthetics, the technology enhances precision, patient outcomes, and the overall quality of healthcare. Additionally, dental applications, such as creating dental crowns and bridges, are rapidly advancing through 3D printing plastics, offering faster and more accurate solutions.
North America
United States
Canada
Asia-Pacific
China
Japan
India
South Korea
Australia
Indonesia
Others
Europe
Germany
France
United Kingdom
Italy
Spain
Russia
Others
Latin America
Brazil
Mexico
Others
Middle East and Africa
North America exhibits a clear dominance, accounting for the largest market share
The market research report has also provided a comprehensive analysis of all the major regional markets, which include North America (the United States and Canada); Asia Pacific (China, Japan, India, South Korea, Australia, Indonesia, and others); Europe (Germany, France, the United Kingdom, Italy, Spain, Russia, and others); Latin America (Brazil, Mexico, and others); and the Middle East and Africa. According to the report, North America accounted for the largest market share.
In the North American region, encompassing countries like the United States and Canada, the 3D printing plastics market thrives due to a combination of factors. The robust technological ecosystem, including research institutions and innovative companies, drives materials and printing techniques advancements. North America's diverse industrial landscape, ranging from aerospace and automotive to healthcare and consumer goods, ensures a wide range of applications for 3D printing plastics.
Moreover, major 3D printing companies and industry pioneers in North America contribute to the market's growth. These companies spearhead technological developments, shape industry standards, and collaborate with other industries to explore new applications. Government support, investment in research and development, and a strong emphasis on innovation further fuel the adoption of 3D printing plastics in North America. Additionally, the region's well-established supply chain and logistics infrastructure provide a solid foundation for distributing and adopting 3D printing materials and technologies.
Top companies are strengthening the market through their strategic innovations and industry leadership. These companies are at the forefront of driving technological advancements that expand the capabilities of 3D printing plastics. By consistently developing new materials with enhanced properties, these industry leaders are broadening the scope of applications, attracting diverse sectors such as aerospace, healthcare, and automotive. Their investments in research and development yield breakthroughs in print speed, accuracy, and material compatibility, thus catalyzing wider adoption. Strategic partnerships with major manufacturers, collaborations with research institutions, and involvement in industry consortia collectively contribute to creating a robust ecosystem for 3D printing plastics. Their influence extends beyond technology, as they play a vital role in educating the market about this technology's benefits and potential applications. Moreover, these companies are nurturing an environment where innovation and customization thrive by offering a range of 3D printing systems, materials, and services. Ultimately, their commitment to pushing the boundaries of 3D printing plastics paves the way for sustained market growth and transformative advancements across industries.
The report has provided a comprehensive analysis of the competitive landscape in the 3D printing plastics market. Detailed profiles of all major companies have also been provided.
3D Systems Inc.
Arkema S.A.
BASF SE
CRP Technology srl
EOS GmbH - Electro Optical Systems
Evonik Industries AG
Henkel AG & Co. KGaA
Materialise NV
Shenzhen Esun Industrial Co. Ltd.
Solvay S.A.
Stratasys Ltd.
Toner Plastics
Solvay S.A. partnered in 2021 with advanced manufacturing solution OEM 9T Labs to bring additively manufactured carbon fiber-reinforced plastic (CFRP) parts to mass production. The collaboration aims to address the challenges of high costs, scrap, and repeatability in using advanced composites. Solvay will focus on developing carbon fiber-reinforced polyetheretherketone (CF/PEEK), CF-reinforced bio-based high-performance polyamides, and CF-reinforced polyphenylene sulfide (CF/PPS) composite materials.
In 2023, Automotive manufacturer Peugeot incorporated Stratasys' 3D printing technology into the interior of its new Inception concept car. The car features a velvet material with 3D printed patterns created using Stratasys' 3DFashion technology. This innovative technology allows for a high level of resolution that traditional methods cannot achieve.
Evonik recently launched a new line of RESOMER Filaments for 3D printing personalized, high-resolution bioresorbable implants. These filaments, designed for Fused Filament Fabrication (FFF) 3D printing systems, offer tight dimensional and chemical specifications, allowing for reproducible implant properties and performance.