Preliminary investigations on extrusion of high viscosity slurry using direct writing technique

Q3 Mathematics International Journal for Simulation and Multidisciplinary Design Optimization Pub Date : 2020-01-01 DOI:10.1051/smdo/2020012

Ali Tesfaye Kebede, E. Balasubramanian, A. Praveen, Lade Rohit, K. Arvind

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引用次数: 2

Abstract

Traditionally solid propellants are manufactured using casting and molding techniques. The effective burning rate of solid propellants is strongly depended on its cross section and geometry. The preparation of mold and mandrel for the manufacturability of various geometric profiles are tedious, time consuming, increases the cost and more human efforts are needed. In order to mitigate these issues, a disruptive technology called additive manufacturing (AM) is in the verge of development. Although the method is effective, additional study must be conducted to improve the flow characteristics of slurries for the high solid loading and there is a huge necessity to reduce the prolonged curing time. The present study focuses on preliminary investigations of extrusion of high viscosity slurry using a pneumatically driven extrusion system. The slurry was prepared with a 80 wt.% solid loading of NaCl having particle sizes of 45 µm and 150 µm, 15.6 wt.% HTPB, 2.2 wt.% TDI, 2.2 wt.% DOA and 0.03 wt.% of ferric acrylacetonate. The slurry was extruded with an aid of pneumatically controlled extruder and each layer was formed. Formed by extruding the slurry using 1.65 mm internal diameter nozzle. Infrared (IR) heater was utilized to transfer the radiational energy for partial curing of each layer and thereby adhesion of other layer was guaranteed. Simulation is performed to determine the temperature distribution using ANSYS platform for comparing the curing temperature of the printed part top surface. Preliminary experiments confirm that extrusion of slurry and heating of each layer can be effectively achieved with the proposed 3D printing technique. Three tensile specimens were produced in accordance with ASTMD 412-C and their corresponding mechanical properties are evaluated. The printed parts have the tensile strength of 0.7 MPa, elongation of 4.85 % and modulus of elasticity of 18.5 MPa which are comparable with the properties of conventional casted part.

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直接书写法挤压高粘度浆料的初步研究

传统的固体推进剂是用铸造和成型技术制造的。固体推进剂的有效燃烧速率在很大程度上取决于其截面和几何形状。各种几何轮廓的可制造性，模具和芯棒的制备繁琐、耗时、成本高，需要更多的人力。为了缓解这些问题，一种名为增材制造(AM)的颠覆性技术正处于发展的边缘。虽然该方法是有效的，但在高固载条件下，还需要进一步的研究来改善浆料的流动特性，缩短固化时间是非常必要的。本研究的重点是利用气动驱动挤压系统对高粘度浆料进行挤压的初步研究。浆料用80 wt。% NaCl固载，粒径为45µm和150µm, 15.6 wt。% HTPB, 2.2 wt。% TDI, 2.2 wt。% DOA和0.03 wt。%的丙烯酸铁。采用气控挤出机对浆料进行挤出，形成各层浆料。采用1.65 mm内径喷嘴挤压浆料形成。利用红外加热器传递辐射能量，使每一层进行部分固化，从而保证其他层的附着力。利用ANSYS平台对打印件顶面固化温度进行了仿真，确定了温度分布。初步实验证实，采用3D打印技术可以有效地实现浆料的挤压和各层的加热。按照ASTMD 412-C标准制作了3个拉伸试样，并对其力学性能进行了评价。打印件的抗拉强度为0.7 MPa，伸长率为4.85%，弹性模量为18.5 MPa，与常规铸件性能相当。

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来源期刊

International Journal for Simulation and Multidisciplinary Design Optimization Mathematics-Control and Optimization

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

16 weeks

期刊介绍： The International Journal for Simulation and Multidisciplinary Design Optimization is a peer-reviewed journal covering all aspects related to the simulation and multidisciplinary design optimization. It is devoted to publish original work related to advanced design methodologies, theoretical approaches, contemporary computers and their applications to different fields such as engineering software/hardware developments, science, computing techniques, aerospace, automobile, aeronautic, business, management, manufacturing,... etc. Front-edge research topics related to topology optimization, composite material design, numerical simulation of manufacturing process, advanced optimization algorithms, industrial applications of optimization methods are highly suggested. The scope includes, but is not limited to original research contributions, reviews in the following topics: Parameter identification & Surface Response (all aspects of characterization and modeling of materials and structural behaviors, Artificial Neural Network, Parametric Programming, approximation methods,…etc.) Optimization Strategies (optimization methods that involve heuristic or Mathematics approaches, Control Theory, Linear & Nonlinear Programming, Stochastic Programming, Discrete & Dynamic Programming, Operational Research, Algorithms in Optimization based on nature behaviors,….etc.) Structural Optimization (sizing, shape and topology optimizations with or without external constraints for materials and structures) Dynamic and Vibration (cover modelling and simulation for dynamic and vibration analysis, shape and topology optimizations with or without external constraints for materials and structures) Industrial Applications (Applications Related to Optimization, Modelling for Engineering applications are very welcome. Authors should underline the technological, numerical or integration of the mentioned scopes.).