13 research outputs found
Ageing (dis)gracefully: Enabling designers to understand material change
From the moment of purchase, pristine objects are subjected to an array of stimuli including
wear, impact, heat, light, water and air which alter their tactile and aesthetic properties. Material
change is often regarded as ‘damage’ or ‘degradation’ and contributes to premature obsolescence but
has potential to be used as a tool to engender emotional engagement with an object and extend
product lifetimes. However, materials resources for designers rarely provide information about how
materials will change in use. In this paper we draw on a combination of literature and user studies to
elucidate the complex web of factors which contribute to changes in material surfaces, which we
present in a ‘framework for understanding material change’. We go on to explore the role that
changes to product material surfaces, and the design of objects to change in particular ways with use,
could have on the transition to circular modes of consumption. A range of resources which aim to
increase designers’ understanding of material change are presented, and the challenges of creating,
utilising and developing these resources are discussed
Morphing in nature and beyond: a review of natural and synthetic shape-changing materials and mechanisms
Shape-changing materials open an entirely new solution space for a wide range of disciplines: from architecture that responds to the environment and medical devices that unpack inside the body, to passive sensors and novel robotic actuators. While synthetic shape-changing materials are still in their infancy, studies of biological morphing materials have revealed key paradigms and features which underlie efficient natural shape-change. Here, we review some of these insights and how they have been, or may be, translated to artificial solutions. We focus on soft matter due to its prevalence in nature, compatibility with users and potential for novel design. Initially, we review examples of natural shape-changing materials—skeletal muscle, tendons and plant tissues—and compare with synthetic examples with similar methods of operation. Stimuli to motion are outlined in general principle, with examples of their use and potential in manufactured systems. Anisotropy is identified as a crucial element in directing shape-change to fulfil designed tasks, and some manufacturing routes to its achievement are highlighted. We conclude with potential directions for future work, including the simultaneous development of materials and manufacturing techniques and the hierarchical combination of effects at multiple length scales.</p
Hygroscapes: Innovative Shape Shifting Façades
This chapter focuses on the testing and design of shape shifting façade prototypes that are programmed to passively sense stimuli and respond in a controlled setting based on the hygroscopic properties of wood. Wood is introduced in this context as a low-tech smart material with a naturally soft responsive mechanism that offers a substitute for mechanical actuators. First, a set of physical experiments were conducted to deduce the design parameters that affect wood morphology, behavior and response time upon changes in humidity levels and moisture content, including dimensional ratio, grain orientation, material thickness, type of wood, and lamination. We then report on the process and outcome of a workshop held at the American University in Cairo, with the main challenge of regulating the morphology and hygroscopic behavior of wood to work as an actuator with specifically desired motion for adaptive building façade prototypes. Based on the observations and analysis of concepts and mechanisms, we discuss shape shifting grammars as a framework for devising adaptive façade prototypes from a generative design perspective, where specific combinations of motion parameters are used to induce semantic rules and customized commands for the overall behavior of shape shifting mechanisms