Computational analysis of hygromorphic self-shaping wood gridshell structures

Grönquist, Philippe; Panchadcharam, Prijanthy; Wood, Dylan; Menges, Achim; Rüggeberg, Markus; Wittel, Falk K.

doi:10.1098/rsos.192210

Cited by 15 publications

(9 citation statements)

References 49 publications

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“…This larger opening angle was selected to maximize Gaussian curvature, which provides an enhanced mechanical advantage by achieving higher stiffness compared to planar structures. [ 59,60 ] The lattices possess four electrically isolated conductive quadrants, which allow individual control of each section of the morphing surface. To improve the actuation stroke, we add simple bilayers to each corner of the lattice, referred to here as “legs.” These legs function to lift and support the lattice body and can be individually actuated.…”

Section: Resultsmentioning

confidence: 99%

Multiscale Heterogeneous Polymer Composites for High Stiffness 4D Printed Electrically Controllable Multifunctional Structures

Morales Ferrer,

Sánchez Cruz,

Caplan

et al. 2023

Advanced Materials

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Abstract4D printing is an emerging field where 3D printing techniques are used to pattern stimuli‐responsive materials to create morphing structures, with time serving as the fourth dimension. However, current materials utilized for 4D printing are typically soft, exhibiting an elastic modulus (E) range of 10−4 to 10 MPa during shape change. This restricts the scalability, actuation stress, and load‐bearing capabilities of the resulting structures. To overcome these limitations, multiscale heterogeneous polymer composites are introduced as a novel category of stiff, thermally responsive 4D printed materials. These inks exhibit an E that is four orders of magnitude greater than that of existing 4D printed materials and offer tunable electrical conductivities for simultaneous Joule heating actuation and self‐sensing capabilities. Utilizing electrically controllable bilayers as building blocks, a flat geometry that morphs into a 3D self‐standing lifting robot is designed and printed, setting new records for weight‐normalized load lifted and actuation stress when compared to other 3D printed actuators. Furthermore, this ink palette is employed to create and print planar lattice structures that transform into various self‐supporting complex 3D shapes. The contributions are integrated into a 4D printed electrically controlled multigait crawling robotic lattice structure that can carry 144 times its own weight.

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Section: Resultsmentioning

confidence: 99%

Multiscale Heterogeneous Polymer Composites for High Stiffness 4D Printed Electrically Controllable Multifunctional Structures

Morales Ferrer,

Sánchez Cruz,

Caplan

et al. 2023

Advanced Materials

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“…The final exploration consists of weaving-inspired prototypes, of which one example is shown in Figure 1-C. A recent study by Grönquist et al (2020) developed a similar approach to obtain double-curved surfaces by relying on the hygromorphic properties of wood. The study proposes the use of narrow wood-strip bilayers that selfshape into a grid shell structure.…”

Section: D Printed Unitsmentioning

confidence: 99%

3D Printed Responsive Wood Interfaces: Shape-Changing Origami-Inspired Prototypes

Vazquez¹,

Gürsoy²

2020

Blucher Design Proceedings

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In this paper, we present a study for a 3D printed responsive wood interface in which we employed a scientific approach to assess the effects of various 3D printing parameters on shape-change. A full factorial design of experiments is conducted to determine the variables that maximize hygromorphic response. Analyzing the results of the experiments, we designed and fabricated origami-inspired prototypes, and tested their bimorph and gradient actuation. The contribution of this study to the growing body of literature on 3D printing responsive woodbased composites is the integration of gradient actuation and origami-inspired shape-changing strategies.

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“…Plants have no muscles or skeletons and rely on differential growth to achieve shape changes [8,9]. Moreover, when a plant dries and shriveled due to water evaporation, which reduces its volume, cell wall constraints dictate the features of the resulting deformation [10,11]. These constraints may take a functional role of movement, for spreading seeds or digging in the sand for germination (Figure 1b).…”

Section: Introductionmentioning

confidence: 99%

Wood Warping Composite by 3D Printing

et al. 2022

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Wood warping is a phenomenon known as a deformation in wood that occurs when changes in moisture content cause an unevenly volumetric change due to fiber orientation. Here we present an investigation of wood warped objects that were fabricated by 3D printing. Similar to natural wood warping, water evaporation causes volume decrease of the printed object, but in contrast, the printing pathway pattern and flow rate dictate the direction of the alignment and its intensity, all of which can be predesigned and affect the resulting structure after drying. The fabrication of the objects was performed by an extrusion-based 3D printing technique that enables the deposition of water-based inks into 3D objects. The printing ink was composed of 100% wood-based materials, wood flour, and plant-extracted natural binders cellulose nanocrystals, and xyloglucan, without the need for any additional synthetic resins. Two archetypal structures were printed: cylindrical structure and helices. In the former, we identified a new length scale that gauges the effect of gravity on the shape. In the latter, the structure exhibited a shape transition analogous to the opening of a seedpod, quantitatively reproducing theoretical predictions. Together, by carefully tuning the flow rate and printing pathway, the morphology of the fully dried wooden objects can be controlled. Hence, it is possible to design the printing of wet objects that will form different final 3D structures.

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Computational analysis of hygromorphic self-shaping wood gridshell structures

Cited by 15 publications

References 49 publications

Multiscale Heterogeneous Polymer Composites for High Stiffness 4D Printed Electrically Controllable Multifunctional Structures

Multiscale Heterogeneous Polymer Composites for High Stiffness 4D Printed Electrically Controllable Multifunctional Structures

3D Printed Responsive Wood Interfaces: Shape-Changing Origami-Inspired Prototypes

Wood Warping Composite by 3D Printing

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