3D pattern development of tight-fitting dress for an asymmetrical female manikin

Tight-fitting clothing pattern reflecting the accurate information of the 3D body shape has been one of the challenges for garment industry especially for those who have an abnormal body shape. The objective of the paper is to develop the process of making a final 2D pattern from 3D scanned surface with minimum errors that fit tightly to an asymmetrical female manikin and secondly, to verify the proposed pattern development process from the free drawn design line on the specific 3D body. On the continuum of the previous methodology which provided the precise flattening algorithm on the local 3D surface, total pattern making process was investigated step by step. Final 2D pattern was constructed using non-extensible fabric and the accuracy of the pattern was investigated by shell-shell deviation of original 3D nude and clothed image. Area of each pattern block and corresponding 3D surface block was compared, and the detailed view of the triangle arrangements for the final pattern examined, confirming the topology of the concave and convex surface reflected correctly in the pattern. As results, the accuracy of the tight-fit dress pattern was satisfactory even for the asymmetrical female manikin with prominent curvature.     

Parametric body model generation for garment drape simulation

A parametric body model generation system has been developed. Using various mathematic and geometric algorithms of this system, a three-dimensionally scanned human body can be converted into a resizable body model. Once a parametric body model is formed, its size and shape can be modified instantaneously by providing appropriate anthropometric data. To facilitate the subsequent pattern arrangement process for garment drape simulation, a bounding box generation algorithm has been developed in this study. Also the model can be converted into a set of parametric surfaces that it can also be used for three-dimensional garment pattern design system.     

Surface pattern comparison among lateral body types flattening 3D figure data

This paper suggests basic information for the improvement of the fit of cloth patterns by lateral body type by comparing the surface patterns of the upper lateral body. The surface patterns were created by projecting three-dimensional figure data onto flattened patterns with a purpose-built software, Patternmaker2008. The resulting surface patterns were compared to explain the differences among lateral body types. Depending on the upper lateral body type, there were significant differences in the parameters related to neck width, lateral neck height, shoulder-dart angle, shoulder angle, back-center angle, and waist-dart ratio. These surface pattern parameters can provide a quantitative basis for the use of lateral shape features in the production of garment patterns and the improvement of upper lateral shape fit.     

Development of a platform for realistic garment drape simulation

An integrated platform for garment drape simulation system has been developed. In this system, garment patterns from conventional two-dimensional CAD systems can be assembled into a three-dimensional garment on a parametrically resizable realistic human body model. A fast and robust particle-based physical calculation engine has been developed for garment shape generation. Then a series of geometric and graphical techniques were applied to create realistic impressions on simulated garments. This system can be used as the rapid prototyping tool for garments in the future quick-response system.     

Garment pattern nesting using image analysis and three-dimensional simulation

A software system has been developed that designs garments made of figured fabrics and arranges the flat patterns on the fabric automatically. A series of image analysis techniques were used to find the repeat unit images of figured fabrics. Three-dimensional garment drape simulation was used to design garments using those repeat unit images as texture maps. Finally, a pattern nesting system was developed to arrange numerous flat garment patterns quickly keeping the continuity of the figures on them. This method could contribute to the increase of the reliability as well as the reduction of production cost by eliminating the unnecessary trial-and-error based processes.     

Wire frame representation of 3D moulded bra cup and its application to example-based design

Fabric or foam sheet moulding is an important manufacturing technique for the apparel industry, in particular for bra production. It is the most economical and convenient method to seamlessly form a garment part into a specified 3D shape. This paper proposes an example-based method for designing moulded bra cups. In this study, a total of 10 typical moulded bra cup specimens were scanned using the Steinbichler Comet white light scanner. Parameterization based remeshing and registration algorithm was used to characterize the 3D shapes of the convex surface of the scanned bra cups. Using an example-based method, virtual master moulds were constructed based on the 3D surfaces of the investigated bra cups after eliminating the style lines and size differences. Then a new bra cup design can be developed from the master mould, either by drawing the style lines in the virtual environment or using scissors to cut the moulded plastic shot along the desired style lines. Different sizes can also be made by grading the wire frame model in 3D manner. The present method will provide a scientific tool for the product development of new bra cups which was conventionally very time-consuming and ineffective.     

Changes in Ensembles’ Thermal Insulation According to Garment’s Fit and Length Based on Athletic Figure

The purpose of this paper is to analyse the impact of design solutions on the thermal insulation of the garments and the ensembles. Previous studies investigated the microclimatic air gaps and volumes, however only under the first - and the second - layered clothing. Since none of the previous studies covered three - layered ensembles, in this study ensembles were accompanied by jackets of different fit and length to investigate the ensembles’ thermal insulation. Variants of bomber jacket differ in the amount of the ease allowance, while variants of the parka differ in length. The thermal insulation of the ensembles increased for 21.6 to 59.7 % when one of the jacket variants was added as the outerwear garment. A threshold volume, after which the thermal insulation will start to decrease due to convection, wasn’t determined for the outerwear third - layered garments nor was the impact of the length of the garment on the thermal insulation clearly stated. This study involved laboratory testing of garments and ensembles by 3D body scanning and thermal manikin measurements. To evaluate the volume of the microclimatic air volume the accurate 3D body scanning was used and the impact of the microclimatic volume on the ensemble’s insulation was tested. The thermal insulation for the selected outerwear garments and afterwards ensembles was measured by resting thermal manikin. Analysis of the results obtained from tests, showed that the garments’ fit and length can be used to model the overall thermal insulation of the ensembles. The ensembles insulation enlargement was measured for microclimatic volumes up to 33.57 dm³ (measured with ensembles accompanied with bomber jacket). The study proved that the limiting microclimatic volume is greater for three - layered clothing, than previously reported. The overall ensembles’ insulation increased simultaneously with the length enlargement (measured with ensembles accompanied with parka jacket). Findings will be of help in the future research on garments and ensembles thermal properties modelled through the design process and the construction.     

Constitutive equations based on cell modeling method for 3D circular braided glass fiber reinforced composites

The cell modeling homogenization method to derive the constitutive equation considering the microstructures of the fiber reinforced composites has been previously developed for composites with simple microstructures such as 2D plane composites and 3D rectangular shaped composites. Here, the method has been further extended for 3D circular braided composites, utilizing B-spline curves to properly describe the more complex geometry of 3D braided composites. For verification purposes, the method has been applied for orthotropic elastic properties of the 3D circular braided glass fiber reinforced composite, in particular for the tensile property. Prepregs of the specimen have been fabricated using the 3D braiding machine through RTM (resin transfer molding) with epoxy as a matrix. Experimentally measured uniaxial tensile properties agreed well with predicted values obtained for two volume fractions.     

Evaluation of elite athletes psycho-physiological responses to compression form-fitted athletic wear in intensive exercise based on 5Ps model

Compression form-fitted athletic wear (CFA) have been widely applied in special sports and various aerobic and fitness activities over recent years. Following the established 5Ps model in our previous study, an evaluation of basic psychophysiological measurements would assist in validating the practicality and effectiveness of these garments for athletic use. The present study was to examine the physiological property and wearing comfort of CFAs on athletes during intensive exercise. Heart rate (HR), blood pressure (BP), myocardial consumption (double product DP), blood oxygen levels (SpO₂), skin and garment temperature (T_sk, T_g) over the athlete’s body were investigated. This study indicated that the application of CFAs maintained the body in the normal SpO₂ range, and produced lower DP and HR compared to those in control condition. The application of CFAs resulted in a decrease on T_sk, which allowed the body quickly to cool down thus avoiding heat stress buildup during and after intensive exercise. The CFAs made by the performance knits with lightweight, gradient compression design and moisture-thermoregulation function presented lower T_g and brought the athletes satisfied wearing comfort perception. This study builds up an understanding on the potential physiological benefits induced by CFAs on athlete’s body in intensive exercise performance.     

Multifunctional melt-mixed Ag/TiO2 nanocomposite PP fabrics: Water vapour permeability, UV resistance, UV protection and wear properties

This research deals with the investigating the effect of nanoparticles on the various properties of nanocomposite fabrics produced from melt spinning of various blend ratios of prepared masterbatch containing Ag/TiO₂ nanoparticles. The results revealed that the wear properties of modified fabrics improved as compared to pure fabrics with a trend justified considering modulus or crystallinity of fabrics with opposite effects. About 40 % UV protection enhancement has been obtained applying this kind of nanoparticles in the close relationship with the crimp contraction of textured yarns. A considerable improvement in the garment comfort has been recorded for nanocomposite sample containing 1 wt% nanoparticles. The lower permeability at low environment temperature and a higher at higher one, as compared to the pure sample, were obtained using this sample. It is highly interesting that these desirable changes in permeability can be achieved in the range of common environment temperatures (15–35 °C) being adapted to the human body requirements. The changing point is about 25 °C exactly meeting the body requirements by changing environment temperatures. A UV-induced solid state nanocomposite interaction increasing wear properties of UV-irradiated nanocomposite fabrics has been discovered.     

Fast garment drape simulation using geometrically constrained particle system

A simulation system for versatile garment drape has been developed. Using this system, the shape of a garment can be simulated in consideration of fabric physical properties as well as the interaction between fabrics and other objects. Each fabric piece in a garment is modeled using a geometrically constrained particle system and its behavior is calculated from an implicit numerical integration algorithm in a relatively short time. The system consists of three modules including a preprocessor for the preparation of fabric patterns and external objects, a postprocessor for the results of three-dimensional visualization, and a drape simulation engine. It can be used for the design process of textile goods, garments, furniture, or upholsteries.     

A new experimental study of influence of fabric permeability, clothing sizes, openings and wind on regional ventilation rates

In this study, a local ventilation rates (VR) measuring system based on stead-state method was developed. This system can measure the local VR of the right arm, the left arm, the chest and the back locations of the upper body garment simultaneously. The whole clothing VR can also be computed. To study the influence of fabric permeability, clothing sizes, hem opening, and wind on local VR of the right arm, the chest and the back of the working garments, 9 jackets with different sizes and fabric permeability (permeable, semi-permeable and impermeable) were made. The results showed that the local VR for each garment location were significantly different. The chest had the largest local VR. Clothing ventilation rates were not liner with garment sizes. Closing garment bottom decreased more air exchange for chest and back comparatively. Wind increased both local and whole VR significantly. But the impacts were different according to different locations.     

The Effects of Omega-3 Fatty Acid on Vitamin D Activation in Hemodialysis Patients: A Pilot Study

The high incidence of cardiovascular disease and vitamin D deficiency in chronic kidney disease patients is well known. Vitamin D activation by omega-3 fatty acid (FA) supplementation may explain the cardioprotective effects exerted by omega-3 FA. We hypothesized that omega-3 FA and 25-hydroxyvitamin D (25(OH)D) supplementation may increase 1,25-dihydroxyvitamin D (1,25(OH)₂D) levels compared to 25(OH)D supplementation alone in hemodialysis (HD) patients that have insufficient or deficient 25(OH)D levels. We enrolled patients that were treated for at least six months with 25(OH)D < 30 ng/mL ({"type":"clinical-trial","attrs":{"text":"NCT01596842","term_id":"NCT01596842"}}NCT01596842). Patients were randomized to treatment for 12 weeks with cholecalciferol supplemented with omega-3 FA or a placebo. Levels of 25(OH)D and 1,25(OH)₂D were measured after 12 weeks. The erythrocyte membrane FA contents were also measured. Levels of 25(OH)D were increased in both groups at 12 weeks compared to baseline. The 1,25(OH)₂D levels at 12 weeks compared to baseline showed a tendency to increase in the omega-3 FA group. The oleic acid and monounsaturated FA content decreased, while the omega-3 index increased in the omega-3 FA group. Omega-3 FA supplementation may be partly associated with vitamin D activation, although increased 25(OH)D levels caused by short-term cholecalciferol supplementation were not associated with vitamin D activation in HD patients.     

Effects of bending properties and drapability on the hand and appearance of wool-blended Fabrics: Comparison of real clothing with online and 3D virtual garments

The purpose of this study was to investigate the effects of bending properties and drapability on the hand and appearance of wool-blended fabrics for comparison of real clothing with online and 3D virtual garments. Objective evaluations were performed by measuring mechanical properties of fabrics, while subjective evaluations were performed by subjects evaluating sensory images of fabrics; real clothing evaluations were performed offline and online, and 3D virtual garments were evaluated. Bending properties and drape coefficients of fabrics were affected by wool blending ratio, and fabrics with high wool blending ratio showed low stiffness, warm-cool, weight, and high smoothness, drapability image. In the real clothing evaluation, stiffness image showed many differences with online evaluation with respect to wool blending ratio. Objective bending properties and drape coefficients showed no correlation with subjective sensory images offline. For the online results, objective mechanical properties had good correlations with all sensory images except smoothness. Stiffness and warm-cool online scores were higher than the offline ones and the offline drapability was higher than the online one for 100 % wool fabrics. Thus, clothing was generally evaluated online as more hard and moist than real clothing. For the virtual garment evaluation, sensory images had no difference according to wool blending ratio compared with real clothing. Many differences in subjective sensory images between real clothing and virtual garments were observed, except for smoothness and weight images. The results showed that it is difficult to exactly predict the hand and appearance of clothing according to fabric properties using 3D virtual garment system.     

Effects of loom characteristics on the physical properties of PET fabrics for emotional clothing

The fabric defects complained by garment manufacturers are stop marks, streaky phenomena on the warp direction, thickness variation and color differences between edges on the right and left sides of the fabrics, which are partly due to the tension variation of warp and weft directions. It is well known that these defects are related to the difference of fabric mechanical property according to the loom characteristics and fabric position such as center and both edges parts of the fabric, which affect garment formability and wearing performance of garment. This research is focusing about which factor is dominant for the difference of fabric mechanical properties which affects garment formability and wearing performance between loom characteristic factor and fabric position factor such as center and both edges of the fabric, which is affected by warp and weft tensions. For this purpose, two kinds of looms were selected, and warp and weft tensions during weaving were measured and the mechanical properties of the fabrics woven by two kinds of looms such as tensile, bending, shear, compression and surface properties were also measured according to the positions such as center and both edge parts of the fabric. These fabric mechanical properties were examined with warp and weft tensions according to the looms and were also analyzed according to the positions of the fabric woven by two kinds of looms. The warp tension on the vicinity of center parts of the looms was much higher than those on the vicinity of both edges of looms. It revealed that the warp tension difference makes differences of fabric mechanical properties such as tensile, bending, shear and surface properties except compressional property. And the differences of these mechanical properties according to the fabric positions and looms seem to make homogeneity of the fabric hand and tailorability of garment deteriorating.     

CAD课程在车辆工程专业教学中的应用

CAD课程是高等学校本科四年制车辆工程专业学生选修的相关计算机应用领域的课程。CAD作为一种现代化的工程设计手段已经步入了工程设计的各个领域。该类课程的目的在于让学生对计算机在绘图与设计领域中所起的作用进行充分的了解,掌握使用计算机绘图与设计的方法。通过对该类课程的学习和上机实训操作,学生能够熟练掌握CAD软件二维、三维零件设计的理论及应用,提高计算机二维、三维辅助设计的能力,为今后进行零件设计和解决工程实际问题提供必要的CAD知识和设计方法。     

Daily rhythm of circulating fat soluble vitamin concentration (A,D, E and K) in the horse

Background  

Many physiological processes of mammalian species exhibit daily rhythmicity. An intrinsic relationship exists between fat soluble vitamins (A, D, E and K) and several body functions. Few investigations on the rhythmic pattern of vitamins in domestic animals have been carried out. The present study evaluated the circadian rhythmicity of fat soluble vitamins in the horse.     

Advanced Strategies for 3D Bioprinting of Tissue and Organ Analogs Using Alginate Hydrogel Bioinks

Alginate is a natural polysaccharide that typically originates from various species of algae. Due to its low cost, good biocompatibility, and rapid ionic gelation, the alginate hydrogel has become a good option of bioink source for 3D bioprinting. However, the lack of cell adhesive moieties, erratic biodegradability, and poor printability are the critical limitations of alginate hydrogel bioink. This review discusses the pivotal properties of alginate hydrogel as a bioink for 3D bioprinting technologies. Afterward, a variety of advanced material formulations and biofabrication strategies that have recently been developed to overcome the drawbacks of alginate hydrogel bioink will be focused on. In addition, the applications of these advanced solutions for 3D bioprinting of tissue/organ mimicries such as regenerative implants and in vitro tissue models using alginate-based bioink will be systematically summarized.     

Ophiobolin O Isolated from Aspergillus ustus Induces G1 Arrest of MCF-7 Cells through Interaction with AKT/GSK3β/Cyclin D1 Signaling

Ophiobolin O is a member of ophiobolin family, which has been proved to be a potent anti-tumor drug candidate for human breast cancer. However, the anti-tumor effect and the mechanism of ophiobolin O remain unclear. In this study, we further verified ophiobolin O-induced G1 phase arrest in human breast cancer MCF-7 cells, and found that ophiobolin O reduced the phosphorylation level of AKT and GSK3β, and induced down-regulation of cyclin D1. The inverse docking (INVDOCK) analysis indicated that ophiobolin O could bind to GSK3β, and GSK3β knockdown abolished cyclin D1 degradation and G1 phase arrest. Pre-treatment with phosphatase inhibitor sodium or thovanadate halted dephosphorylation of AKT and GSK3β, and blocked ophiobolin O-induced G1 phase arrest. These data suggest that ophiobolin O may induce G1 arrest in MCF-7 cells through interaction with AKT/GSK3β/cyclin D1 signaling. In vivo, ophiobolin O suppressed tumor growth and showed little toxicity in mouse xenograft models. Overall, these findings provide theoretical basis for the therapeutic use of ophiobolin O.     

Highly porous three-dimensional poly(lactide-co-glycolide) (PLGA) microfibrous scaffold prepared by electrospinning method: A comparison study with other PLGA type scaffolds on its biological evaluation

In this study, a three-dimensional (3D) poly(lactide-co-glycolide) (PLGA) microfibrous scaffold with high porosity (ca. 90 % porosity) was developed for evaluating its performance in tissue engineering application. A dope solution of PLGA/polyethylene oxide (PEO) blend was electrospun into a methanol coagulation bath for fabricating highly porous 3D PLGA scaffold and a salt leaching method was used for making interconnected pores of 100?C200 ??m size inside the scaffold. The morphological structure, pore size and porosity of the microfibrous scaffold were determined, and compared with twodimensional (2D) mat-type and 3D sponge-type of PLGA scaffold. Also, swelling ratio, water uptake and compressive strength were compared in order to elucidate the structure-property relationships of different types of the scaffolds, especially in a wet condition. As a result of scanning electron microscopy (SEM) observation, normal human dermal fibroblasts (nHDF) were migrated, attached, and proliferated well inside the 3D scaffold. MTT assay confirmed that the highly porous 3D PLGA microfibrous scaffold had superior cell adhesion and proliferation abilities due to fibrous structure of large specific surface area, and interconnected pore structure. Therefore, this high performance 3D PLGA scaffold can have a high potentiality for application in tissue engineering in comparison with conventional PLGA scaffolds.