3D Printing of Liquid Crystal Elastomer Actuators PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download 3D Printing of Liquid Crystal Elastomer Actuators PDF full book. Access full book title 3D Printing of Liquid Crystal Elastomer Actuators by Arda Kotikian. Download full books in PDF and EPUB format.
Author: Arda Kotikian
Publisher:
ISBN:
Category : Actuators
Languages : en
Pages : 0
Get Book Here
Book Description
Soft robotics offer advantages over their rigid counterparts due to the intrinsic softness of their consisting materials, soft robotic matter. When equipped with programmable shape morphing and controllable function, soft robotics are best qualified for interaction with delicate objects, exploration of unknown terrains, and large, impact-resistant deformations. Towards this goal, new materials and fabrication methods are needed to create actuators with programmable shape- morphing behavior akin to human muscles. Liquid crystal elastomers (LCEs) are soft materials comprised of anisotropic liquid crystal mesogen molecules, which when aligned, give rise to reversible contraction with high energy density when heated above their nematic-to-isotropic transition temperature (TNI). However, the ability to produce LCE actuators with programmed director alignment in arbitrary, bulk forms is a grand challenge. The focus of my Ph.D. thesis is to create programmable LCE actuators through the integration of design, synthesis, and multi-material 3D printing methods. Towards this goal, solvent-free, oligomeric LCE inks were synthesized that incorporate rigid mesogens along their backbone as well as photopolymerizable groups at the chain ends. By varying the molecular composition of these oligomeric species, LCE inks with the appropriate viscoelastic response were designed for high operating temperature-direct ink writing (HOT-DIW), an extrusion-based 3D printing method. By tailoring polymer backbone and crosslinking chemistries of our LCE inks, their TNI could be varied from 92°C to 127°C after printing and UV cross-linking, and enable custom thermal response. We further demonstrated that patterned LCEs with programmed director alignment along the print path were produced when printing in the nematic phase. These 3D LCEs exhibit large reversible contractility and high specific energy density. Our integrated approach allows for prescribed LCE alignment in arbitrary geometric motifs. Building on this seminal advance, we created untethered soft robotic matter that repeatedly shape-morphs and self-propels in response to thermal stimuli through passive control. Specifically, we designed and printed active LCE hinges with orthogonal director alignment that interconnect rigid polymeric tiles. These hinges can be programmed as mountain or valley folds to produce reversible active origami structures. Moreover, in a single structure, we programmed hinges made of LCEs with disparate TNI to enable sequential folding and demonstrated untethered, reversible sequential folding in soft, active origami for the first time. We further demonstrated a self- compacting prism with a modular geometric locking mechanism capable of sequential folding with three temperature-specific, stable configurations. To enable the informed design of untethered robotic matter, LCE hinge bending angle and torque can be prescribed by geometry and LCE chemistry. We then exploited their exemplary performance by programming LCE hinges into the "rollbot", an exemplar self-propelling structure with passive control. Specifically, we designed a pentagonal prism with low TNI LCE hinges and propellers with high TNI LCE hinges, informed by our torque and bending angle characterization, enabling reversible reconfiguration and self- propulsion across a heated surface. To expand upon these capabilities, ewe developed a novel method of 3D printing aligned LCE filaments with embedded, coaxial liquid metal by co-extrusion of LCE and liquid metal through a core-shell nozzle. Our innervated LCE (iLCE) fibers are electrothermally heated well above TNI with programmable and predictable heat generation through the core of the filament, which resulted in large, prescriptible contractile strains akin to those of our neat 3D printed LCEs. The iLCE fibers enable self-sensing of actuation through the resulting change of resistance with respect to actuation strain, where a change of resistance is directly predictable from strain. Moreover, our iLCEs exhibited reliable reversible actuation and considerable work output, which combined with self-sensing capabilities allows for closed loop control. Specifically, our actuators automatically reach target resistance and strain values rapidly and repeatedly despite large bias load perturbations. As a final demonstration, we patterned iLCEs with a spiral printpath to demonstrate programmable 3D shape morphing. Analogous to iLCE fibers, these spiral iLCEs were electrothermally heated, exhibited self-sensing, and were regulated with closed loop control. In summary, we have developed a new platform for creating soft robotic matter through the design, synthesis, and assembly of LCE inks, which can be seamlessly integrated with structural, sensing, and functional materials. Our platform may be harnessed for applications including soft robotics, reconfigurable electronics, adaptable structures, and well beyond.
Author: Arda Kotikian
Publisher:
ISBN:
Category : Actuators
Languages : en
Pages : 0
Get Book Here
Book Description
Soft robotics offer advantages over their rigid counterparts due to the intrinsic softness of their consisting materials, soft robotic matter. When equipped with programmable shape morphing and controllable function, soft robotics are best qualified for interaction with delicate objects, exploration of unknown terrains, and large, impact-resistant deformations. Towards this goal, new materials and fabrication methods are needed to create actuators with programmable shape- morphing behavior akin to human muscles. Liquid crystal elastomers (LCEs) are soft materials comprised of anisotropic liquid crystal mesogen molecules, which when aligned, give rise to reversible contraction with high energy density when heated above their nematic-to-isotropic transition temperature (TNI). However, the ability to produce LCE actuators with programmed director alignment in arbitrary, bulk forms is a grand challenge. The focus of my Ph.D. thesis is to create programmable LCE actuators through the integration of design, synthesis, and multi-material 3D printing methods. Towards this goal, solvent-free, oligomeric LCE inks were synthesized that incorporate rigid mesogens along their backbone as well as photopolymerizable groups at the chain ends. By varying the molecular composition of these oligomeric species, LCE inks with the appropriate viscoelastic response were designed for high operating temperature-direct ink writing (HOT-DIW), an extrusion-based 3D printing method. By tailoring polymer backbone and crosslinking chemistries of our LCE inks, their TNI could be varied from 92°C to 127°C after printing and UV cross-linking, and enable custom thermal response. We further demonstrated that patterned LCEs with programmed director alignment along the print path were produced when printing in the nematic phase. These 3D LCEs exhibit large reversible contractility and high specific energy density. Our integrated approach allows for prescribed LCE alignment in arbitrary geometric motifs. Building on this seminal advance, we created untethered soft robotic matter that repeatedly shape-morphs and self-propels in response to thermal stimuli through passive control. Specifically, we designed and printed active LCE hinges with orthogonal director alignment that interconnect rigid polymeric tiles. These hinges can be programmed as mountain or valley folds to produce reversible active origami structures. Moreover, in a single structure, we programmed hinges made of LCEs with disparate TNI to enable sequential folding and demonstrated untethered, reversible sequential folding in soft, active origami for the first time. We further demonstrated a self- compacting prism with a modular geometric locking mechanism capable of sequential folding with three temperature-specific, stable configurations. To enable the informed design of untethered robotic matter, LCE hinge bending angle and torque can be prescribed by geometry and LCE chemistry. We then exploited their exemplary performance by programming LCE hinges into the "rollbot", an exemplar self-propelling structure with passive control. Specifically, we designed a pentagonal prism with low TNI LCE hinges and propellers with high TNI LCE hinges, informed by our torque and bending angle characterization, enabling reversible reconfiguration and self- propulsion across a heated surface. To expand upon these capabilities, ewe developed a novel method of 3D printing aligned LCE filaments with embedded, coaxial liquid metal by co-extrusion of LCE and liquid metal through a core-shell nozzle. Our innervated LCE (iLCE) fibers are electrothermally heated well above TNI with programmable and predictable heat generation through the core of the filament, which resulted in large, prescriptible contractile strains akin to those of our neat 3D printed LCEs. The iLCE fibers enable self-sensing of actuation through the resulting change of resistance with respect to actuation strain, where a change of resistance is directly predictable from strain. Moreover, our iLCEs exhibited reliable reversible actuation and considerable work output, which combined with self-sensing capabilities allows for closed loop control. Specifically, our actuators automatically reach target resistance and strain values rapidly and repeatedly despite large bias load perturbations. As a final demonstration, we patterned iLCEs with a spiral printpath to demonstrate programmable 3D shape morphing. Analogous to iLCE fibers, these spiral iLCEs were electrothermally heated, exhibited self-sensing, and were regulated with closed loop control. In summary, we have developed a new platform for creating soft robotic matter through the design, synthesis, and assembly of LCE inks, which can be seamlessly integrated with structural, sensing, and functional materials. Our platform may be harnessed for applications including soft robotics, reconfigurable electronics, adaptable structures, and well beyond.
Author: Mark Warner
Publisher: Oxford University Press
ISBN: 9780199214860
Category : Mathematics
Languages : en
Pages : 423
Get Book Here
Book Description
This text is a primer for liquid crystals, polymers, rubber and elasticity. It is directed at physicists, chemists, material scientists, engineers and applied mathematicians at the graduate student level and beyond.
Author: Jaap MJ den Toonder
Publisher: Royal Society of Chemistry
ISBN: 1849737096
Category : Technology & Engineering
Languages : en
Pages : 279
Get Book Here
Book Description
Cilia are tiny hairs covering biological cells to generate and sense fluid flow. Millions of years of evolution have inspired a novel technology which is barely a decade old. Artificial cilia have been developed to control and sense fluid flow in microscopic systems, presenting new and interesting options for flow control in lab-on-a-chip devices. This appealing link between nature and technology has seen rapid development in the last few years, and this book presents a review of the state-of-the-art in the form of a professional reference book. The editors have pioneered the field, having initiated a major European project on this topic soon after its inception. Active researchers in academia and industry will benefit from the comprehensive nature of this book, while postgraduates and those new to the field will gain a clear understanding of the theory, techniques and applications of artificial cilia.
Author: Morgan Barnes
Publisher:
ISBN:
Category :
Languages : en
Pages :
Get Book Here
Book Description
4D printing, where a printed structure undergoes shape changes when exposed to a stimuli, is a promising method to develop actuators for applications in soft-robotics and biomedical devices where complex structures are required that might be difficult to create using traditional fabrication methods. However, most 4D printing uses shear allignment upon printing to create aligned liquid crystal or composite fibers that undergo anisotropic expansions/contraction when actuated. This limits the types of shape changes available to researchers as determining the print path required to induce a desired shape change is not trivial. Here, we use a new reactive printing method that enables the printing of a dual network liquid crystal elastomer (LCE) which can be mechanically programmed into the desired shape change. First, a thiol-acrylate Michael addition is completed upon printing an LCE oligomer solution into a catalyst bath. Next, the printed structure is dried, deformed to a desired shape change, and UV cured to crosslink excess acrylates in the network. The resulting LCE transforms between the printed and mechnically deformed shape when heated and cooled, respectively, and is capable reversible strains up to 100%. We demonstrate the versatility of this method by printing a variety of LCE actuators which could not be printed using conventional 4D printing methods.
Author: Cedric Paul Ambulo
Publisher:
ISBN:
Category : Actuators
Languages : en
Pages :
Get Book Here
Book Description
Liquid crystal elastomers (LCEs) are potential artificial muscle candidates within patientassistive devices. Their stimuli-responsive, shape-morphing properties can be controlled by various processes to produce a wide range of actuation behaviors. However, there are inherent processing limitations that inhibit their application within biomedical devices: 1) force and work constraints due to size restrictions, 2) high activation temperatures (≥ 100 °C) to induce actuation, and 3) incompatible power delivery. The aim of my research is to develop manufacturing processes to fabricate three-dimensional LCE artificial muscles compatible with patient-assistive devices. The developed 4D printing process enables control over geometry and liquid crystalline orientation to develop 3D LCE structures with improved actuation behaviors. The development of tunable, printable LCE chemistries allows for low-temperature activation suitable for human body interfacing. Incorporation of liquid metal fillers generates a multiresponsive LCE composite compatible with facile power delivery systems, i.e., current and light. The enabled processing freedom for this class of LCEs can be exploited within a myriad of assistive devices ranging from untethered, implantable dynamic valves to wearable, rehabilitative artificial muscles.
Author: Kun Zhou
Publisher: Springer Nature
ISBN: 3031047214
Category : Technology & Engineering
Languages : en
Pages : 334
Get Book Here
Book Description
This book focuses on the advances of additive manufacturing in the applications of wearable electronics, energy storage, biomedical implants and devices, drug delivery, and technologies for 4D printing, large-scale printing, and ceramics printing. It provides timely insights into the materials, functionalities, and applications of additive manufacturing.
Author: Derek A. Paley
Publisher: Springer Nature
ISBN: 303050476X
Category : Technology & Engineering
Languages : en
Pages : 301
Get Book Here
Book Description
This book includes representative research from the state‐of‐the‐art in the emerging field of soft robotics, with a special focus on bioinspired soft robotics for underwater applications. Topics include novel materials, sensors, actuators, and system design for distributed estimation and control of soft robotic appendages inspired by the octopus and seastar. It summarizes the latest findings in an emerging field of bioinspired soft robotics for the underwater domain, primarily drawing from (but not limited to) an ongoing research program in bioinspired autonomous systems sponsored by the Office of Naval Research. The program has stimulated cross‐disciplinary research in biology, material science, computational mechanics, and systems and control for the purpose of creating novel robotic appendages for maritime applications. The book collects recent results in this area.
Author: Hyun Kim
Publisher:
ISBN:
Category : Actuators
Languages : en
Pages :
Get Book Here
Book Description
Liquid crystal elastomers (LCEs) are well-recognized for programmable, large strain, and reversible shape changes in response to external stimuli. However, so far, there are several issues preventing the use of this class of materials in practical engineering applications such as actuators and electronics. The first part of the dissertation focuses on synthesis and processing strategies to expand capabilities of LCEs for actuator applications. Engineering application of LCEs are often limited by poor static and dynamic mechanical properties, e.g., modulus (~10 MPa), toughness (~10 MPa), blocking stress (~500 kPa), and work capacity (~300 kJ/m3 ). Also, these materials require high temperatures (typically above 100 °C) to undergo shape change. This work enables significant improvement in mechanical properties of LCEs by combining liquid crystallinity and semi-crystallinity. By developing novel synthesis and processing methods, crystallized LCEs are capable of not only enhanced static mechanical properties, including modulus (~350 MPa) and toughness (~40 MPa) but also improved dynamic mechanical properties, including blocking stress (~1.3 MPa) work capacity (~730 kJ/m3 ). This work also describes two routes to create multi-responsive LCE actuators that overcome the need to externally heat the material to high temperatures. We show high speed (~380 rpm) torsional actuation in response to chemical stimuli. Moreover, we provide a facile way to create programmed LCEs and carbon nanotubes (CNTs) composites. The LCE/CNT composites utilize visible light or electricity to trigger high-speed bending (~1 s) or uniaxial actuation (work capacity ~100 kJ/m3 , 2.5 times higher than mammalian muscles). The second part of the dissertation discusses electronic applications of LCEs. As current micro-electronic fabrication requires 2D flat substrates for photolithography processing, resulting devices are limited in 2D geometry which has minimal strain tolerance. Also, polymer-based biomedical electronics, e.g., neural interfaces, have significant issue to achieve long-term reliable encapsulation in the physiological condition. This work enables to process electronics on programmed 2D LCE substrates, then morph to desired 3D structures. The 3D electronics on LCE substrates provide strain tolerance up to 100% of deformation. We further show various examples of 3D electronics including strain tolerant capacitors and temperature sensing antenna enabled by LCE substrates. In the end, we briefly discuss current and on-going research to utilize LCEs for reliable packaging for advanced biomedical devices, e.g., deployable neural probes.
Author: Yoseph Bar-Cohen
Publisher: SPIE Press
ISBN: 9780819452979
Category : Artificial organs
Languages : en
Pages : 790
Get Book Here
Book Description
Covers the field of EAP with attention to all aspects and full infrastructure, including the available materials, analytical models, processing techniques, and characterization methods. This second edition covers advances in EAP in electric EAP, electroactive polymer gels, ionomeric polymer-metal composites, and carbon nanotube actuators.
Author: Hideko Koshima
Publisher: John Wiley & Sons
ISBN: 3527346201
Category : Technology & Engineering
Languages : en
Pages : 442
Get Book Here
Book Description
Offers a comprehensive review of the research and development of mechanically responsive materials and their applications in soft robots Mechanically Responsive Materials for Soft Robotics offers an authoritative guide to the current state of mechanically responsive materials for the development of soft robotics. With contributions from an international panel of experts, the book examines existing mechanically responsive materials such as crystals, polymers, gels, and composites that are stimulated by light and heat. The book also explores the application of mechanical materials to soft robotics. The authors describe the many excellent mechanical crystals developed in recent years that show the ability to bend, twist, rotate, jump, self-heal, and shape memory. Mechanical polymer materials are described for evolution into artificial muscles, photomobile materials, bioinspired soft actuators, inorganic-organic hybrid materials, multi-responsive composite materials, and strain sensor materials. The application of mechanical materials to soft robots is just the beginning. This book reviews the many challenging and versatile applications, such as soft microrobots made from photoresponsive elastomers, four-dimensional printing for assembling soft robots, self-growing of soft robots like plants, and biohybrid robots using muscle tissue. This important book: -Explores recent developments in the use of soft smart materials in robotic systems -Covers the full scope of mechanically responsive materials: polymers, crystals, gels, and nanocomposites -Deals with an interdisciplinary topic of advanced smart materials research -Contains extensive descriptions of current and future applications in soft robotics Written for materials scientists, polymer chemists, photochemists, physical chemists, solid state chemists, inorganic chemists, and robotics engineers, Mechanically Responsive Materials for Soft Robotics offers a comprehensive and timely review of the most recent research on mechanically responsive materials and the manufacture of soft robotics.
