The harvesting of piezoelectricity through the human body involves the conversion of mechanical energy, mostly generated by the repeated movements of the body, to electrical energy, irrespective of the time and location. In this research, it was expected that the garment design would play an important role in increasing the efficiency of piezoelectricity scavenged in a garment because the mechanical deformation imposed on the energy harvester could increase through an optimal design configuration for the garment parts supporting a piezoelectricity harvester. With this expectation, this research aimed to analyze the effect of the clothing factors, and that of human factors on the efficiency of piezoelectricity harvesting through clothing in joint movements. These analyses resulted in that the efficiency of the piezoelectricity harvesting was affected from both two clothing factors, tightness level depending upon the property of the textile material and design configuration of the garment part supporting the piezoelectricity harvesting. Among the three proposed designs of the garment part supporting the piezoelectricity harvesting, 'reinforced 3D module design,' which maximized the value of radius in the piezoelectricity harvester, showed the highest efficiency across all areas of the joints in the human body. The two human factors, frequency of movement and body part, affected the efficiency of the piezoelectricity harvesting as well.
In the fashion industry, one of the most important things is to accurately analyse the consumers’ emotional response to current fashion trends and to forecast trends for the forthcoming season based on the analysed results. In this study, it was assumed that a more accurate trend‐forecasting for a market would be possible, if the fluctuation of consumer emotion could be represented on a kind of macroscopic model of recent fashion trends. For an exploratory attempt to acquire such macroscopic information on trends, this research aimed to (1) propose a systematic method to derive a macroscopic model on trends on the basis of consumer emotion; and (2) develop a macroscopic model on recent fashion trends, applying the method. This research was based on three assumptions: (1) Fashion trend is a representation of change in consumers’ emotions; (2) A linguistic representation can be a useful medium to access consumers’ emotions; and (3) Consumers’ emotions can be represented as a concrete model. As a method of developing the macroscopic model, a five‐step procedure was proposed and executed in this research. According to the five‐step procedure, a total of four surveys were serially conducted and the data sets were analysed quantitatively or qualitatively. As a result, a two‐dimensional macroscopic model on recent fashion trend was developed, in which 79 major emotion descriptors were positioned and categorized into 14 subgroups. ‘artificial‐natural’ (for the first dimension) and ‘simple‐complicated’ (for the second dimension) appeared as the two‐dimensional axes passing through the macroscopic model on recent fashion trends. The 14 subgroups in the model corresponded to the main themes of recent fashion trends reported in the literature on fashion.
Textile-based triboelectric nanogenerators (TENGs) have received considerable attention for wearable applications owing to their significant advantages, such as flexibility, lightness, and breathability. Recently, several studies based on the modification of friction surfaces for improving the triboelectric output performance have been reported. However, previously reported methods require complicated fabrication processes and may deteriorate the intrinsic properties of a textile. Herein, we present a wearable TENG utilizing a textile composed of pile-embroidered (rough-textured) fibers as a contact surface. The deformability of the fibers originating from the suspended structure provides a large contact area that can participate in triboelectrification. This significantly increases charge density induced on the surface in response to a compressive force, resulting in a high output voltage of 113 V. The TENG also exhibits a high output power, which is 24 times higher than that of the TENG based on satin-embroidered (flat-textured) fibers. More importantly, owing to the conventional textile manufacturing process based on three-dimensional embroidery, the fabrication of our TENG is significantly simpler and more cost-effective than previously reported techniques. Experimental demonstrations as a wearable energy harvester highlight the utility of the TENG for generating electricity from various human motions. Based on ease of manufacturing and high output performance, the proposed harvester is a promising candidate as a low-cost power source for nextgeneration electronics, such as Internet of Things devices and self-powered smart clothing.
In this research, we investigated the luminance efficiency of the computerized embroidery methods applied to flexible plastic optical fiber (POF) for realization of the textile display. Due to the nature of the flexible POF being similar to that of textile yarn, it has been possible to realize a flexible textile display by application of some adjusted fabrication methods. However, besides the simple property of flexibility, two requirements are still demanded for the flexible POF-based textile display: high luminance and the method for realization of pixels in a display. Among the fabrication methods, machine embroidery has feasibility to realize relatively higher luminance of flexible POF-based textiles through a simple procedure. The aim of this study is to evaluate of the feasibility of the embroidery method for the flexible POF-based textile display in terms of luminance, and an approach for a suitable condition in the embroidery method to realize the textile display. To do this, four embroidery methods, in which bending angles from around 90° to around 180° were applied to the flexible POF, were developed in this study. The measurement method was conducted identically on two types of POFs (flexible POFs and non-flexible POFs). The measurement points were selected in consideration of the distance from the light source and the rotation angle of the embroidery, depending on each embroidery design. Based on the resulting luminance efficiency according to the four embroidery methods, suitable conditions for the embroidery method to realize a relatively higher level of luminance for the textile display were suggested.
-This research developed a textile coil inductor, in which conductive yarn was wound spirally onto textile, and produced an energy harvesting module utilizing a cylindrical compression coil spring structure to allow a permanent magnet to spin in the center hole of the coil inductor. The study confirmed through a pilot test that the voltage increased as the number of laminated layers of the coil inductor increased. Five subjects were tested in the energy harvesting measuring experiment after producing a sports shoe insole-mounted energy harvesting module. While the subjects executed sports motions such as walking and running at five given frequencies, the peak-to-peak voltage was measured by an oscilloscope and the accumulated energy voltage of the calculated rms voltage (Vrms) and the peak power (㎼) were derived. The output voltage increased as the frequency increased and the average Vp-p (V) of the five subjects was 0.53 V, the average peak power (㎼) was 0.289 ㎼, and the Vrms (V) was 0.065 V. This research is significant in that it suggests the possibility of an energy harvesting module based upon the textile coil inductor emerging from the former shoes' energy generator packaging method for heavy shoe types by developing a lightweight, flexible, and humanfriendly footgear module structure.
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