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用于熔融沈积成型 (FDM) 技术的 3D 打印机市场 - 2023-2028 年预测Fused Deposition Modeling (FDM) Technology 3D Printer Market - Forecasts from 2023 to 2028 |
预计 2021 年全球熔融沈积成型 3D 打印机市场价值 142790.8 万美元,预测期内復合年增长率为 29.40%,到 2028 年将达到 867528.9 万美元。
熔融沈积成型,或简称为 FDM,是一种增材製造工艺,通过喷嘴挤出材料,然后将各层粘合在一起以产生三维结构。 传统的基于 FDM 的 3D 打印机通过加热的喷嘴挤出基于聚合物的细丝,将其熔化并以二维层的形式沉积到构建平台上。 这些层被加热并粘合在一起,形成最终的三维部件。 FDM 由于其易于使用和相对较高的生产率,如今已被广泛使用。 它被用于医疗保健、汽车和航空航天等各个领域。
与 FDM 3D 打印相关的合同和采购正在推动市场增长。
例如,2021年8月,Etihad Engineering与EOS签署了研发合作协议,使用SLS & FDM 3D打印技术开发飞机内饰件。 同样在 2020 年 8 月,飞机製造服务提供商 AM Craft 从 Stratasys 购买了四台新的 F900 FDM 3D 打印机,用于开发经过认证的飞机内饰 3D 打印部件,例如面板、管道和座椅。我希望它会成为现实。 该公司已经拥有四台 F450mc 3D 打印机,这次额外购买是其提高 3D 打印能力战略的一部分。
FDM 3D 打印市场正被主要参与者积极利用,更新和升级现有的 FDM 打印服务和解决方案。
3D 打印软件提供商 Mango 3D 已于 2022 年 12 月更新了其 Lychee 打印准备程序以支持 FDM。 通过这次升级,Lychee 使用户能够在同一平台上将这项技术与 FDM 一起使用,并以高效的方式生成文件以供输出。 除了轻鬆准确地切割模型外,该软件还为用户提供了批量生产工具以及实时镂空、孤岛检测和压力杯检测功能。 Mango 3D 的 Beta FDM 切片功能旨在帮助 3D 打印领域的新用户优化他们的结果,而无需获得深厚的技术知识。
全球 FDM 3D 打印机市场也受益于新产品的发布和主要参与者的业务扩张,以推出增强型产品并巩固其市场地位。
Creality 是一家主要的 3D 打印运营商,已于 2023 年 2 月发布了一款新的 FDM 3D 打印机 CR-M4。 它具有网络属性,可以更轻鬆地设置打印工作室并一次生产多个批次,并且可以一次打印大量设计。 CR-M4 通过创建一个带有两个 Z 轴和支撑桿的高刚性三角形来确保稳定的顶部框架。 可应用于建筑、医疗保健等各个领域。 其主要特点是打印温度高、多台打印机控制、打印量大、打印可靠。
在医疗保健领域,对FDM 3D打印的需求越来越大,其应用领域也越来越广泛。
在医疗保健行业,FDM 3D 打印可以帮助创建类似于真实人体组织的人造肌肉和组织,并可用于替代手术。 製造商使用这种打印服务来生产组织和肌肉以外的各种部位。 使用这种印刷机的最大优势之一是可以对任何设计进行复杂而精确的定制,并进行多次修改。 此外,还可以根据医疗保健专业人员的反馈和建议进行更改和修改,为患者提供更舒适、更健康的治疗和假肢。 FDM 3D 打印机还可用于以精确的方式製造训练模型和手术计划原型,确保最佳训练。
熔融沈积建模技术 3D 打印机在航空航天和国防工业中得到高效使用,在汽车行业中同样有效。
熔融沈积建模用于航空航天和国防工业,以支持航天器、飞机、导弹和其他国防相关产品的高效开发和製造。 这些 FDM 广泛用于快速原型製作和加工应用。 此外,汽车行业使用这些熔融沈积建模来製造和製作汽车零件原型。 这种 FDM 技术更加有益,因为它有助于降低与新车开发相关的成本和时间。 这项新技术对于提供灵活性和卓越设计至关重要,使製造商能够根据他们的特定要求创建定制的汽车零件。
按地区划分,熔融沈积建模 (FDM) 技术 3D 打印机市场分为北美、南美、欧洲、中东和非洲以及亚太地区。 北美的熔融沈积建模 (FDM) 技术 3D 打印机市场具有很大的市场规模,因为它广泛应用于医疗保健等多个行业,因为熔融沈积建模技术 3D 打印机可以生产经济的假肢设备。 它还常用于航空航天和汽车行业,以开展高效的研究和设计。 在这方面,这些行业在北美地区的增长有望为熔融沈积建模 (FDM) 技术 3D 打印机创造有利可图的机会。
Fused deposition modeling, or simply FDM, is an additive manufacturing process that involves the extrusion of materials through a nozzle and the subsequent joining of those layers to produce three-dimensional structures. A conventional FDM 3D printer uses a heated nozzle to force a polymer-based filament through it, melting it and depositing it on the build platform as 2D layers. These layers combine while they are still heated to eventually form a three-dimensional part. FDM is extensively used currently as it is easily accessible and relatively productive. It can be used in a variety of fields, including healthcare and the automobile and aerospace sectors.
For instance, in August 2021, Etihad Engineering formed an R&D collaboration agreement with EOS where the company will be using SLS & FDM 3D printing for the development of aircraft interior parts. Also, in August 2020, aircraft manufacturing service provider AM Craft purchased four new F900 FDM 3D printers from Stratasys, which would enable the former in developing certified 3D printed parts for aircraft interiors including paneling, ducting, and seating. The company already consists of four F450mc 3D printers and such addition came as part of its strategy to improve its 3D printing capacity.
Mango 3D, a provider of software for 3D printing, updated its Lychee print preparation program to make it FDM compatible in December 2022. With this upgrade, Lychee provided users the ability to employ this technology along with FDM on the same platform to generate files for output in an efficient way. The software offers users batch production tools along with real-time hollowing, island detection, and pressure cup detection capabilities in addition to making it simple and precise to slice models. The beta FDM slicing capabilities of Mango 3D are intended to assist users just joining the field of 3D printing in optimizing outcomes without requiring them to get in-depth technical knowledge.
Creality, a significant 3D printing business introduced a new FDM 3D printer, the CR-M4 in February 2023. It has networking characteristics that make it simpler to set up a print studio and generate numerous batches at once, and it can print a vast range of designs at once. A stable top frame is ensured by the CR- M4's creation of a stiff triangle with two Z-axis and support rods. It can be applied to a variety of fields, including architecture and healthcare. Its primary characteristics include a high print temperature, multiple printer control, huge print volume capability, and dependable printing.
In the healthcare industry, FDM 3D printing contributes to the creation of synthetic muscles and tissues that resemble real human tissues and can be utilized in replacement surgery. Manufacturers use these printing services to produce a wide range of parts apart from tissues and muscles. One of the biggest advantages of using such printing devices is that any design can be intricately and precisely customized and designed in addition to it being equipped with several modifications. It can also be changed and modified based on the feedback and suggestions of the healthcare professionals, which ensures that the treatment or prosthetic that is equipped is much more comfortable and healthy for the patient. FDM 3D printers can also be used for the manufacturing of training models and surgical planning prototypes in an accurate way, which ensures optimal training.
The use of fused deposition modeling in aerospace and defence supports the efficient development as well as manufacturing of spacecraft, aircraft, missiles as well as in other defense-related products. These FDM's are widely used in terms of rapid prototyping as well tooling applications. Moreover, in the automotive industry, these fused deposition modelings are used for manufacturing as well as prototyping car parts. This FDM technology is further beneficial as it supports reducing the cost associated with the development of new cars as well as they are time-saving. This new technology is imperative in offering flexibility and great design which further enables the manufacturers in creating customized car parts based on their particular requirements.
By geography, the fused deposition modeling (FDM) technology 3D printer market has been segmented into North America, South America, Europe, the Middle East and Africa, and the Asia Pacific. North America's fused deposition modeling (FDM) technology 3D printer market is anticipated to reach a sizeable market value as the fused deposition modeling technology 3D printer is widely used in multiple industries such as in healthcare owing to their capability in producing economic prosthetic wear. It is also commonly used in the aerospace and automotive industry with the motive of developing efficient research and design. In this regard, the growth of these industries in the North American region is expected to create lucrative opportunities for the fused deposition modeling (FDM) technology 3D printer.