A multi-physics approach for modeling hygroscopic behavior in wood low-tech architectural adaptive systems

Abstract Wood is a natural engineering material that has traditionally been exploited in design for a wide variety of applications. The recent demand for sustainable material and construction processes in the construction industry has triggered a renewed interest and research in the inherent properties of wood and their derived applications, and specifically for developing low-tech architectural adaptive systems. This paper focuses on the physical and computational modeling of the morphing behavior of wood through hygroscopic expansion or contraction to a high degree of precision. The amount of stress related to the hygroscopic shrinking or swelling ranges from almost zero to high values, and its prediction is fundamental to alleviate any fatigue challenges. The capability of designing wood composite whose stress state remains limited under changes of the environmental humidity is beneficial for any engineering application subjected to a repeated reversal of loading such as adaptive systems. In this paper, a mechanical model, together with its numerical implementation, is presented; the model is benchmarked against some prototypical experiments, performed by using real material parameters. The control parameter in the model is the relative moisture change in wood that determines the orthotropic swelling/de-swelling phenomenon, and is coupled with the elastic behavior of wood. This model is integrated into a programmable matter design approach that combines physical and computational exploration. The approach is illustrated for a hygro-morphic building facade panel. The approaches and algorithms presented in this paper have further applications for computer-aided design of smart materials and systems with interchanging functionalities.

[1]  I. D. Cave Modelling moisture-related mechanical properties of wood Part II: Computation of properties of a model of wood and comparison with experimental data , 1978, Wood Science and Technology.

[2]  Suong V. Hoa Factors affecting the properties of composites made by 4D printing (moldless composites manufacturing) , 2017 .

[3]  R. Bruce Hoadley,et al.  Understanding Wood: A Craftsman's Guide to Wood Technology , 1980 .

[4]  Matteo Pezzulla,et al.  Steady and transient analysis of anisotropic swelling in fibered gels , 2015 .

[5]  Tiantian Yang,et al.  Dynamic Sorption and Hygroexpansion of Wood Subjected to Cyclic Relative Humidity Changes. II. Effect of Temperature , 2010 .

[6]  M. Gurtin,et al.  An introduction to continuum mechanics , 1981 .

[7]  I. D. Cave Modelling moisture-related mechanical properties of wood Part I: Properties of the wood constituents , 1978, Wood Science and Technology.

[8]  C. Skaar,et al.  Dynamic sorption and hygroexpansion of wood wafers exposed to sinusoidally varying humidity , 1983, Wood Science and Technology.

[9]  Markus Rüggeberg,et al.  Bio-Inspired Wooden Actuators for Large Scale Applications , 2015, PloS one.

[10]  K. Rocens,et al.  Hygromechanical behaviour of wooden composites , 1997, Wood Science and Technology.

[11]  Achim Menges,et al.  Material computation—4D timber construction: Towards building-scale hygroscopic actuated, self-constructing timber surfaces , 2016 .

[12]  I. D. Cave A theory of the shrinkage of wood , 1972, Wood Science and Technology.

[13]  Stefano Gabriele,et al.  Swelling and growth: a constitutive framework for active solids , 2017 .

[14]  H. A. Schroeder,et al.  Shrinking and Swelling Differences Between Hardwoods and Softwoods , 2007 .

[15]  Robert J. Ross,et al.  Wood handbook : wood as an engineering material , 2010 .

[16]  Nicholas Negroponte,et al.  Soft Architecture Machines , 1976 .

[17]  Daniel Keunecke,et al.  Moisture-dependent orthotropic elasticity of beech wood , 2011, Wood Science and Technology.