Composite-resin systems for direct digital additive manufacturing

用于直接数字增材制造的复合树脂系统

• 批准号: RGPIN-2015-06431
• 负责人: Boluk, Yaman
• 金额: $ 1.82万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=638043
• 关键词: Composite; resin; systems; direct; digital

Direct Digital Additive Manufacturing (DDAM) which is also called as Solid Freeform Fabrication is a production method of making three-dimensional (3D) objects by layer by layer printing. The growth of DDAM is expected to be exponential once it reaches to its turning point. 3D printed structures made of polymeric composites may find broad range of applications such as prototypes, medical and dental products, sporting goods, and spare parts. Fused deposition modelling (FDM), stereolithography (SL) and selective laser sintering (SLS) are current DDAM methods to create parts with controlled architecture and composition. Among them, SL is based on photopolymerization in a curable monomer bath by UV laser beam. SLS is based on inkjet printing and melt fusion of polymer powder on selected areas by infrared laser beam. FDM is based on micro extrusion of thermoplastic molten filaments and their deposition layer by layer. Advantages of SL and SLS are speed and high resolution. The primary advantage of FDM technology is its ability to create almost any shape or geometric feature. On the other hand both SL and SLS generate waste from the cleaning of uncured or unmolten segments. Weak mechanical properties are the disadvantages of all of those methods (SL, SLS and FDM) and limit their applications. Whether cured or fused layers, they have limited formation of interpenetrating polymer networks among polymer particles and layers . Thus they generate weak interparticle (layer) bonding and weld lines. In addition die drool, sag and swell are other problems of FDM which are inherited from conventional plastic extrusion processes. The goal of my program is to address those problems by the discovery of Reactive Extruded Deposition (RED) process. Cellulose nanocrystal (CNC)-polyurethane composites will be used as materials. Selected diisocyanates will be mixed with CNC dispersed polyols and delayed time controlled catalysts in a micromixing chamber. Then, the mixture will be deposited before polymerization starts by the computer controlled micro capillary. Delayed polymerization will take place, once successive layers are deposited and diffusion of molecules among layers takes place. Polyurethanes are selected because of their tunable mechanical and biocompatible properties, suitable for their wide range of applications. On other side, CNC particles will play two roles: First of all, the rheology of the deposition and settling stages will be controlled by CNC particles. Secondly, rod-shaped CNC particles with high modulus of elasticity (134 GPa) will give the desired mechanical properties to finished products at low concentrations with percolation. The program will have five parts: 1) Preparation of monomers; 2) Grafting CNC and dispersing in polyols; 3) Micro mixing and microchannel flow; 4) Rheokinetics of catalytic polymerization and weld formation; 5) Mechanical properties of layered deposition.

直接数字增材制造（DDAM），也称为实体自由成型制造，是一种通过逐层打印制造三维（3D）物体的生产方法。DDAM的增长预计将是指数一旦达到其转折点。由聚合物复合材料制成的3D打印结构可以找到广泛的应用，例如原型，医疗和牙科产品，体育用品和备件。熔融沉积成型（FDM），立体光刻（SL）和选择性激光烧结（SLS）是当前的DDAM方法，用于创建具有受控结构和成分的零件。其中，SL是基于通过UV激光束在可固化单体浴中的光聚合。SLS基于喷墨打印和通过红外激光束在选定区域上熔融聚合物粉末。FDM基于热塑性熔融长丝的微挤出和它们逐层沉积。SL和SLS的优点是速度和高分辨率。FDM技术的主要优点是它能够创建几乎任何形状或几何特征。另一方面，SL和SLS都产生清洁未固化或未熔融段的废物。所有这些方法（SL，SLS和FDM）的缺点是机械性能差，限制了它们的应用。无论是固化层还是熔融层，它们在聚合物颗粒和层之间具有有限的互穿聚合物网络的形成。因此，它们产生弱的颗粒间（层）结合和熔接线。此外，模头流液、凹陷和膨胀是FDM的其它问题，其从常规塑料挤出工艺继承。我的计划的目标是通过发现反应挤出沉积（RED）工艺来解决这些问题。纤维素纤维（CNC）-聚氨酯复合材料将被用作材料。选定的二异氰酸酯将与CNC分散的多元醇和延迟时间控制的催化剂在微混合室中混合。然后，混合物将在聚合开始之前通过计算机控制的微毛细管沉积。一旦连续的层被沉积并且分子在层之间发生扩散，将发生延迟聚合。选择聚乙烯是因为其可调的机械和生物相容性，适合其广泛的应用。另一方面，CNC颗粒将起到两个作用：首先，沉积和沉降阶段的流变性将由CNC颗粒控制。其次，具有高弹性模量（134 GPa）的棒状CNC颗粒将在低浓度下通过渗滤为成品提供所需的机械性能。该计划将有五个部分：1）单体的制备; 2）接枝CNC和分散在多元醇中; 3）微混合和微通道流动; 4）催化聚合和焊缝形成的流变学; 5）层状沉积的机械性能。