Your search keyword '"Xiong, Xiaoman"' showing total 36 results

1. Serum interleukin-33 combined with FEF75% z-score and FeNO improves the diagnostic accuracy of asthma in children

Author

Yang, Qiuyan, Zheng, Yuehong, Dong, Junjun, Xu, Qingrong, Li, Shufang, Li, Aijun, Xiong, Xiaoman, and Zhang, Yanli

Published

2024

2. Simple determination of key structural parameters for fibrous materials enabled by Ergun-Type and Kozeny-type equations

Author

Yang, Tao, Hu, Lizhu, Yu, Deyou, Xiong, Xiaoman, Chvojka, Jiří, Venkataraman, Mohanapriya, Petrů, Michal, Tomková, Blanka, Morikawa, Hideaki, and Militký, Jiří

Published

2022

3. The role of 14-3-3β in acute asthma in children and analysis of the risk factors for asthma exacerbation.

Author

Li, Shufang, Dong, Junjun, Li, Aijun, Yang, Qiuyan, Xiong, Xiaoman, Xie, Xueli, and Zhang, Yanli

Subjects

ASTHMA in children, LEUCOCYTES, LOGISTIC regression analysis, DISEASE exacerbation, RECEIVER operating characteristic curves

Abstract

Objective: To investigate the role of 14-3-3β in acute asthma exacerbations in children and analyze the risk factors for asthma exacerbations. Methods: This study recruited 101 children with acute asthma exacerbations, 101 children with stable asthma, and 65 healthy children. Serum 14-3-3β was compared among the three groups. Factors such as asthma family history, skin prick test, serum-specific IgE test, coinfections, and clinical indicators (FeNO, FEV1, white blood cells, eosinophils, and serum IgE level) were compared between the asthma groups. Risk factors associated with acute asthma exacerbations were identified using multivariate logistic regression models. ROC curve was drawn to determine the diagnostic sensitivity and specificity of 14-3-3β. Results: Serum 14-3-3β was significantly greater in the acute asthma group than in the stable asthma and control groups. Serum 14-3-3β was higher in severe acute asthma group than in mild-moderate asthma group. There were no significant differences in serum 14-3-3β levels between stable asthma and control groups (p >.05). Multivariate logistic regression analysis revealed that serum 14-3-3β level, FeNO, coinfection, and FEV1 z-score significantly increased the odds of acute asthma exacerbations in children. The optimal 14-3-3β cutoff value (39.79 ng/mL), had a sensitivity of 69.3% and specificity of 94.1% for predicting acute asthma exacerbations. Conclusions: 14-3-3β is elevated in children with acute exacerbations of asthma, and increases with exacerbation severity. 14-3-3β, FeNO, FEV1, and coinfection could be independent risk factors for predicting asthma exacerbations. The optimal 14-3-3β cutoff value for predicting asthma exacerbations was 39.79 ng/mL. [ABSTRACT FROM AUTHOR]

Published

2024

4. Experimental and Modelling Studies on Thermal Insulation and Sound Absorption Properties of Cross-Laid Nonwoven Fabrics

Author

Yang Tao, Hu Lizhu, Xiong Xiaoman, Petrů Michal, Palanisamy Sundaramoorthy, Yang Kai, Novák Jan, and Militký Jiří

Subjects

thermal insulation, sound absorption, nonwoven, polyester, Textile bleaching, dyeing, printing, etc., TP890-933

Abstract

Nonwoven fabrics are widely used for thermal insulation and sound absorption purpose in construction and automobile fields. It is essential to investigate their thermal conductivity and sound absorption coefficient. Five cross-laid nonwoven fabrics are measured on the Alambeta device and Brüel & Kjær impedance tube. Bogaty and Bhattacharyya models are selected to predict the thermal conductivity, and Voronina and Miki models are used to predict the sound absorption coefficient. The predicted thermal conductivity shows a significant difference compared with the measured values. It is concluded that Bogaty and Bhattacharyya models are not suitable for high porous nonwoven fabric. In addition, the results of Voronina and Miki models for sound absorption prediction are acceptable, but Voronina model shows lower mean prediction error compared with Miki model. The results indicate that Voronina model can be used to predict the sound absorption of cross-laid nonwoven fabric.

Published

2021

5. Application of Acoustical Method to Characterize Nonwoven Material

Author

Yang, Tao, Xiong, Xiaoman, Wang, Yuanfeng, Mishra, Rajesh, Petrů, Michal, and Militký, Jiří

Published

2021

6. Thermal Behavior of Aerogel-Embedded Nonwovens in Cross Airflow

Author

Xiong Xiaoman, Venkataraman Mohanapriya, Jašíková Darina, Yang Tao, Mishra Rajesh, Militký Jiří, and Petrů Michal

Subjects

nonwoven fabrics, silica aerogel, cross airflow, heat transfer coefficient, Textile bleaching, dyeing, printing, etc., TP890-933

Abstract

Thermal performance of aerogel-embedded polyester/polyethylene nonwoven fabrics in cross airflow was experimentally studied by using a laboratory-built dynamic heat transfer measuring device in which the fabric could be applied on a heating rod. Experiments were performed with different airflow velocities and heating conditions. The temperature–time histories of different materials were collected and compared. The temperature difference and convective heat transfer coefficient under continuous heating were analyzed and discussed. Results showed that under preheated conditions, the aerogel-embedded nonwoven fabrics had very small decrease in temperature and good ability to prevent against heat loss in cross flow. As for the continuous heating conditions, the heat transfer rate of each material showed an increasing trend with increase in the Reynolds number. The aerogel-treated nonwoven fabric with the least fabric thickness and aerogel content delivered a significantly increased heat transfer rate at higher Reynolds number. Thicker fabrics with higher aerogel content could provide better insulation ability in cross flow.

Published

2021

7. Effect of silanization on copper coated milife fabric with improved EMI shielding effectiveness

Author

Periyasamy, Aravin Prince, Yang, Kai, Xiong, Xiaoman, Venkataraman, Mohanapriya, Militky, Jiri, Mishra, Rajesh, and Kremenakova, Dana

Published

2020

8. A study of some airflow resistivity models for multi-component polyester fiber assembly

Author

Yang, Tao, Mishra, Rajesh, Horoshenkov, Kirill V., Hurrell, Alistair, Saati, Ferina, and Xiong, Xiaoman

Published

2018

9. Insights into the large‐size graphene improvement effect of the mechanical properties on the epoxy/glass fabric composites.

Author

Peng, Qingyan, Tan, Xiaodong, Xiong, Xiaoman, Wang, Yuanfeng, Novotná, Jana, Shah, Kaushal Vipul, Stempień, Zbigniew, Periyasamy, Aravin Prince, Kejzlar, Pavel, Venkataraman, Mohanapriya, and Militky, Jiri

Subjects

GLASS composites, EPOXY resins, GRAPHENE, SCANNING electron microscopes, TENSILE strength, CHEMICAL properties

Abstract

In this study, we investigated how the chemical structural properties, mechanical properties, and morphology of large‐size graphene platelets (LGPs) doped glass fabric (GF)/epoxy composites are affected by varying loading amounts of LGPs. Scanning electron microscope results revealed that the dispersion and filling effect of LGPs can improve the flowability of the resin, reducing the aggregation and shrinkage of the resin on the glass fabric surface, thereby facilitating better resin infiltration and coverage of the glass fabric surface. From the spectrum analysis, the binding of LGPs with epoxy resin was the physical combination, without new chemical groups generated during the curing process. The addition of LGPs improved the ratio of the crystalline phases in the composites, from 30.00% of the GF/epoxy to 57.50% of the GF/epoxy@2.2LGPs. Mechanical properties indicated that the composites exhibited greater tensile strength than pure GF, which progressively increased with increasing LGPs content until it reached 1.5 wt%, then the tensile strength starts to decrease. And the GF/epoxy@1.5 LGPs exhibited 136% enhancement in tensile strength compared to other carbon fillers reinforced composites, which achieved a satisfactory enhancement under relatively low loading content. Highlights: The effect of the large‐size graphene platelets (LGPs) on the properties of glass fabric (GF)/epoxy composites.Compared to the glass fabric/epoxy composite, the LGPs doped composite possessed a much higher storage modulus (E′).The LGPs doped composite exhibited 136% enhancement in tensile strength compared to other carbon fillers reinforced composites.The addition of LGPs improved the ratio of the crystalline phases in the composites. [ABSTRACT FROM AUTHOR]

Published

2023

10. Investigation on acoustic behavior and air permeability of struto nonwovens

Author

Yang, Tao, Xiong, Xiaoman, Mishra, Rajesh, Novák, Jan, Chaloupek, Jiří, Sanetrnik, Filip, and Militký, Jiří

Published

2016

11. Transport properties of aerogel-based nanofibrous nonwoven fabrics

Author

Xiong, Xiaoman, Yang, Tao, Mishra, Rajesh, and Militky, Jiri

Published

2016

12. Acoustical Evaluation and Comparative Study of Maple Leaves and Coir and Polyester Fibers.

Author

Yang, Tao, Hu, Lizhu, Xiong, Xiaoman, Venkataraman, Mohanapriya, Petrů, Michal, Novák, Jan, and Militký, Jiří

Subjects

POLYESTER fibers, COIR, ABSORPTION of sound, MAPLE, COMPARATIVE studies, POLYESTERS

Abstract

Copyright of Journal of Natural Fibers is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

13. Sound Absorption Properties and Accuracy of Prediction Models on Natural Fiber Based Nonwoven Materials.

Author

Yang, Tao, Hu, Lizhu, Xiong, Xiaoman, Yu, Deyou, Petrů, Michal, Yang, Kai, Novák, Jan, and Militký, Jiří

Subjects

ABSORPTION of sound, PREDICTION models, POLYESTER fibers, COTTON fibers, WOOL, NATURAL fibers, NONWOVEN textiles

Abstract

Copyright of Journal of Natural Fibers is the property of Taylor & Francis Ltd and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

14. Experimental and Modelling Studies on Thermal Insulation and Sound Absorption Properties of Cross-Laid Nonwoven Fabrics.

Author

Yang, Tao, Hu, Lizhu, Xiong, Xiaoman, Petrů, Michal, Palanisamy, Sundaramoorthy, Yang, Kai, Novák, Jan, and Militký, Jiří

Subjects

SOUNDPROOFING, THERMAL insulation, NONWOVEN textiles, AUTOMOTIVE engineering, ABSORPTION coefficients, ABSORPTION of sound

Abstract

Nonwoven fabrics are widely used for thermal insulation and sound absorption purpose in construction and automobile fields. It is essential to investigate their thermal conductivity and sound absorption coefficient. Five cross-laid nonwoven fabrics are measured on the Alambeta device and Brüel & Kjær impedance tube. Bogaty and Bhattacharyya models are selected to predict the thermal conductivity, and Voronina and Miki models are used to predict the sound absorption coefficient. The predicted thermal conductivity shows a significant difference compared with the measured values. It is concluded that Bogaty and Bhattacharyya models are not suitable for high porous nonwoven fabric. In addition, the results of Voronina and Miki models for sound absorption prediction are acceptable, but Voronina model shows lower mean prediction error compared with Miki model. The results indicate that Voronina model can be used to predict the sound absorption of cross-laid nonwoven fabric. [ABSTRACT FROM AUTHOR]

Published

2022

15. A study of characterization on polyester fibrous panels and their homogeneity assessment

Author

Yang, Tao, Saati, Ferina, Groby, Jean-Philippe, Xiong, Xiaoman, Petrů, Michal, Mishra, Rajesh, Militký, Jiří, Marburg, Steffen, Technical University of Liberec, Technische Universität Munchen - Université Technique de Munich [Munich, Allemagne] (TUM), Laboratoire d'Acoustique de l'Université du Mans (LAUM), Centre National de la Recherche Scientifique (CNRS)-Le Mans Université (UM), and Le Mans Université (UM)-Centre National de la Recherche Scientifique (CNRS)

Subjects

homogeneity, Characterization, bayesian reconstruction, polyester fibrous materials, porous materials, [PHYS.MECA.ACOU]Physics [physics]/Mechanics [physics]/Acoustics [physics.class-ph]

Abstract

International audience; Nowadays, fibrous polyester materials are becoming one of the most important alternatives for controlling reverberation time by absorbing unwanted sound energy in the automobile and construction fields. Thus, it is worthy and meaningful to characterize their acoustic behavior. To do so, non-acoustic parameters, such as tortuosity, viscous and thermal characteristic lengths and thermal permeability, must be determined. Representative panels of polyester fibrous material manufactured by perpendicular laying technology are thus tested via the Bayesian reconstruction procedure. The estimated porosity and airflow resistivity are found in good agreement with those tested via direct measurements. In addition, the homogeneity of polyester fibrous panels was characterized by investigating the mean relative differences of inferred non-acoustic parameters from the direct and reverse orientation measurements. Some parameters, such as tortuosity, porosity and airflow resistivity, exhibit very low relative differences. It is found that most of the panels can be assumed homogeneous along with the panel thickness, the slight inhomogeneity mostly affecting the thermal characteristic length.

Published

2020

16. Preparation of electrosprayed composite coated microporous filter for particulate matter capture.

Author

Peng, Qingyan, Yang, Kai, Venkataraman, Mohanapriya, Tan, Xiaodong, Xiong, Xiaoman, Novotna, Jana, Karpiskova, Jana, Hruza, Jakub, Stuchlík, Martin, and Militky, Jiri

Subjects

PARTICULATE matter, COMPOSITE coating, POLYTEF, GRAPHITE, POLYPROPYLENE

Abstract

Particulate matter 2.5 (PM 2.5.) pollution is a serious threat to human health. In this paper, we firstly used electrospraying technology to fabricate composite polytetrafluoroethylene (PTFE)/expanded graphite (EG) coated spun‐bond polypropylene (PP) microporous filters that show tremendous potential for its use as an effective PM 2.5. capture medium. The surface morphology, the surface area, the surficial chemical structure, the hydrophobicity, the antifouling ability, the mechanical property, the air permeability, and the filtration efficiency (FE) of the prepared composite PTFE/EG coated microporous filters were investigated. It is found that with the increase of EG content, the surface area of the filter tended to increase, and the pore size decreased correspondingly. Physical adhesion between the PTFE or PTFE/EG and the PP fabric is found. The composite PTFE/EG coated spun‐bond PP microporous filter exhibits an excellent hydrophobicity and antifouling ability. Compared with the original spun bond PP, the FE of the composite PTFE/EG coated spun bond PP microporous filter for PM 2.5. is significantly increased from 52.18% to 85.00%, and the quality factor (QF) increases from 0.0238 to 0.0431. These results indicate that the composite PTFE/EG coated spun‐bond PP microporous filter is an excellent material for PM 2.5. capture. [ABSTRACT FROM AUTHOR]

Published

2022

17. Determination of the permeability coefficient and airflow resistivity of nonwoven materials.

Author

Yang, Tao, Hu, Lizhu, Petrů, Michal, Wang, Xiaomeng, Xiong, Xiaoman, Yu, Deyou, Mishra, Rajesh, and Militký, Jiří

Subjects

DARCY'S law, AIR flow, PERMEABILITY, PRESSURE drop (Fluid dynamics), FINITE element method

Abstract

Air penetration behavior plays a vital role in the performance of fibrous material in various industrial applications. Two parameters, the permeability coefficient and airflow resistivity, can describe the air penetration behavior of fibrous material. FX 3300 Textech Tester III and AFD300 AcoustiFlow devices were used to respectively characterize the permeability coefficient and airflow resistivity of nonwoven materials. Nonwoven samples were compressed due to the load from the test head of the FX 3300. Finite element analysis along with the mathematical method were implemented to recover the airflow permeability of samples at the uncompressed state. The effects of pressure drop on the airflow velocity and permeability coefficient were analyzed by the Ergun-type model. The determination of airflow resistivity based on the permeability coefficient is carried out via two approaches, that is, the direct method and the extrapolation method. The results show that the airflow velocity is not linearly related to the pressure drop, which differs from Darcy's law. This non-linear relation is mainly attributed to the influence of frictional loss. By comparing the relative error between assessed and measured airflow resistivity, most of the assessed values of the compressed samples are overestimated. The results also suggest that the direct and extrapolation methods are applicable to assess airflow resistivity on an airflow velocity (or air permeability) test device. Moreover, the Ergun-type model is also applicable to determine the permeability coefficient and airflow resistivity of nonwoven materials. [ABSTRACT FROM AUTHOR]

Published

2022

18. A comparison of fabric structures for carbon fiber reinforced composite: Laminated and orthogonal woven structures.

Author

Yang, Tao, Hu, Lizhu, Xiong, Xiaoman, Wang, Yuanfeng, Wang, Xiaomeng, Petrů, Michal, Zhang, Shangyong, Mishra, Rajesh, and Militký, Jiří

Subjects

FIBROUS composites, LAMINATED materials, CARBON fibers, YARN, COMPOSITE structures, CARBON composites

Abstract

In this research, orthogonal structure carbon fiber reinforced composite was developed and its properties were compared with those of laminated structure composite. To solve the problem of yarn damage caused by friction during the weaving process, a custom‐built weaving device was build up. Compression and vacuum‐assisted resin infusion molding (VARIM) techniques were selected and compared. It was found that fiber geometries could be well retained using the later one. The orthogonal and laminated composites prepared by the VARIM technique with the fiber volume fraction were 32.76% and 38.64%, respectively. Flexure and impact tests were performed to evaluate the properties of laminated and orthogonal composites. The results show that orthogonal composite exhibits superior properties in the warp and weft directions. In addition, due to its straight yarn path and insertion of carbon fiber in the through‐thickness direction, orthogonal fabric reinforced composite exhibits an improved bending strength over composites reinforced by laminated plain woven fabric, although the fiber volume fraction of orthogonal composite is much lower than that of laminated composite. The findings indicate that orthogonal structure composite provides profound guiding significance for product development and application of carbon fiber composite. [ABSTRACT FROM AUTHOR]

Published

2021

19. An experimental evaluation of convective heat transfer in multi-layered fibrous materials composed by different middle layer structures.

Author

Xiong, Xiaoman, Venkataraman, Mohanapriya, Jašíková, Darina, Yang, Tao, Mishra, Rajesh, Militký, Jiří, and Petrů, Michal

Subjects

HEAT convection, HEAT transfer coefficient, LASER engraving, AEROGELS, REYNOLDS number

Abstract

In this work, three types of multi-layered fibrous materials with different middle layer structures, including Struto nonwoven, Struto nonwoven with air pockets and Struto nonwoven with air pockets filled by aerogel particles, were prepared based on laser engraving technique and laminating method. A custom-built new device was fabricated to evaluate convective thermal behaviour of the multi-layered materials in cross flow. It was found that in cross flow the heat transfer coefficient of the multi-layered material with encapsulated aerogels is directly proportional to Reynolds number. There are considerable variances in heat transfer rates of the three structures at low airflow velocity (less than 10 m/s), but the values are very close at high airflow velocity. It is concluded that the air pockets and aerogels present in the multi-layered fibrous material have significant effect on convective thermal behaviour of the overall structure in cross flow. The finding is a new contribution to the field of aerogel-based fibrous materials as thermal insulators in building and industrial facilities. [ABSTRACT FROM AUTHOR]

Published

2021

20. Study on the sound absorption behavior of multi-component polyester nonwovens: experimental and numerical methods.

Author

Yang, Tao, Saati, Ferina, Horoshenkov, Kirill V, Xiong, Xiaoman, Yang, Kai, Mishra, Rajesh, Marburg, Steffen, and Militký, Jiří

Subjects

ABSORPTION of sound, ACOUSTICS, POLYESTERS, POLYESTER fibers, SURFACE impedance, ABSORPTION coefficients

Abstract

This study presents an investigation of the acoustical properties of multi-component polyester nonwovens with experimental and numerical methods. Fifteen types of nonwoven samples made with staple, hollow and bi-component polyester fibers were chosen to carry out this study. The AFD300 AcoustiFlow device was employed to measure airflow resistivity. Several models were grouped in theoretical and empirical model categories and used to predict the airflow resistivity. A simple empirical model based on fiber diameter and fabric bulk density was obtained through the power-fitting method. The difference between measured and predicted airflow resistivity was analyzed. The surface impedance and sound absorption coefficient were determined by using a 45 mm Materiacustica impedance tube. Some widely used impedance models were used to predict the acoustical properties. A comparison between measured and predicted values was carried out to determine the most accurate model for multi-component polyester nonwovens. The results show that one of the Tarnow model provides the closest prediction to the measured value, with an error of 12%. The proposed power-fitted empirical model exhibits a very small error of 6.8%. It is shown that the Delany–Bazley and Miki models can accurately predict surface impedance of multi-component polyester nonwovens, but the Komatsu model is less accurate, especially at the low-frequency range. The results indicate that the Miki model is the most accurate method to predict the sound absorption coefficient, with a mean error of 8.39%. [ABSTRACT FROM AUTHOR]

Published

2019

21. Sound absorption and compression properties of perpendicular-laid nonwovens.

Author

Yang, Tao, Xiong, Xiaoman, Mishra, Rajesh, Novák, Jan, and Militký, Jiří

Subjects

ABSORPTION of sound, NONWOVEN textiles, FIBER orientation, POROSITY, TEXTILE industry

Abstract

This study presents an investigation into the sound absorption behavior and compression properties of perpendicular-laid nonwovens. Seven types of perpendicular-laid nonwovens produced by vibrating and rotating perpendicular lappers were selected. Nonwovens with varying thickness and areal density were prepared by the heat-pressing method to investigate the effect of structural parameters such as thickness and areal density on sound absorption ability. Measurements of sound absorption properties were carried out with a Brüel and Kjær measuring instrument. The effect of manufacturing techniques on sound absorption performance and compression properties was investigated. The effect of porosity on sound absorption ability was studied. The influence of density and fiber orientation angle on compression properties was analyzed. The results show that samples prepared by vibrating perpendicular lapper exhibit better compression properties, whereas there is no significant influence of two manufacturing techniques on sound absorption performance. The increase of areal density results in improvement in the sound absorption ability. The increase of thickness can improve the sound absorption coefficient in the low-frequency range, but decrease of the coefficient occurred in the high-frequency range. A quadratic relationship between porosity and sound absorption ability has been found. The results also show that compressional resistance has a strong relation with density – the correlation coefficient is 0.95, indicating that the compressional resistance is directly proportional to the density of perpendicular-laid nonwovens. The results indicate that the perpendicular-laid nonwovens with higher initial fiber orientation angle have better compression properties. [ABSTRACT FROM AUTHOR]

Published

2019

22. Investigation on sound absorption properties of aerogel/polymer nonwovens.

Author

Yang, Tao, Xiong, Xiaoman, Venkataraman, Mohanapriya, Mishra, Rajesh, Novák, Jan, and Militký, Jiří

Subjects

AEROGELS, ABSORPTION of sound, NONWOVEN textiles, POROUS materials, NOISE control

Abstract

This paper presents an investigation on sound absorption performance of aerogel/polymer nonwoven fabrics. Polyester/polyethylene nonwovens embedded with hydrophobic amorphous silica aerogel were chosen for sound absorption measurements. The sound absorption coefficient (SAC) of single and laminated layers of aerogel nonwovens blankets was tested by Brüel and Kjær impedance tube, the noise reduction coefficient (NRC) was used for numerical analysis. A sound absorption index was developed to analyze the effect of aerogel content on sound absorption ability. The effect of air-back cavities on SAC of single-layer aerogel/polymer nonwoven fabrics was investigated. The results show that there is a decrease in SAC with the increase of aerogel content. It is observed that the NRC linearly increased with the increase of layers for all the samples. It was also found that the air-back cavities result in resonance phenomenon, as the increase in thickness of air-back cavities the peak values of SAC shift toward lower frequencies. [ABSTRACT FROM AUTHOR]

Published

2019

23. Electrospun nanofibrous membranes embedded with aerogel for advanced thermal and transport properties.

Author

Venkataraman, Mohanapriya, Mishra, Rajesh, Militky, Jiri, Xiong, Xiaoman, Marek, Jaromir, Yao, Juming, and Zhu, Guocheng

Subjects

ELECTROSPINNING, AEROGELS, THERMAL insulation, NANOFIBERS, HEAT transfer, DIFFERENTIAL scanning calorimetry

Abstract

The primary purpose of cold weather clothing is to shield the wearer from the extremities of the external environment. The thermal properties of nanofibers and their potential applications have tremendous scope and application in this area. The objective of this study was to investigate the mechanisms of heat transfer through fibrous insulation where the fiber diameter was less than 1 μm. Electrospinning process was used to produce flexible polyurethane and polyvinylidene fluoride nanofibers embedded with silica aerogel. The thermal and transport behavior of the samples was evaluated, and results were statistically analyzed. Presence of aerogel particles were confirmed through microscopic examination. Thermal behavior was investigated by using thermogravimetric analysis and differential scanning calorimetry. The results showed that the polyvinylidene fluoride nanofibrous membranes embedded with aerogel obtained a good thermal stability with lower weight loss than polyurethane nanofibrous membranes. The glass transition and melting point was not affected by the aerogel content in the layers, validating that polymers are not miscible. The increase in duration of electrospinning led to higher web thickness, which resulted in considerable decrease in air permeability. Considerable improvement of thermal insulation was observed by increasing the number and the weight per unit area of both nanofibrous membranes. The results confirmed increase in thermal insulation by embedding silica aerogel in nanofibrous membranes. With reference to the results, it could be concluded that nanofibers embedded with aerogel are good for thermal insulation in cold weather conditions. Thermal insulation battings incorporating nanofibers could possibly decrease the weight and bulk of current thermal protective clothing. [ABSTRACT FROM AUTHOR]

Published

2018

24. Thermal and compression characteristics of aerogel-encapsulated textiles.

Author

Xiong, Xiaoman, Yang, Tao, Mishra, Rajesh, Kanai, Hiroyuki, and Militky, Jiri

Subjects

AEROGELS, THERMAL insulation, TEXTILE lamination, COMPRESSION loads, MICROENCAPSULATION, THERMAL conductivity

Abstract

In this work, a new approach to apply silica aerogel into textiles by laser treatment and laminating technique was used to fabricate aerogel-encapsulated textiles. Thermal insulation performance of the prepared multilayer aerogel-encapsulated laminated fabrics was characterized in terms of thermal conductivity, thermal resistance and thermal diffusivity by Alambeta instrument. Infrared thermography data were collected by FLIR ThermaCAM TVS300 thermal camera. The ORIENTEC STA-1225 Universal Testing Machine was employed for testing the compression properties like compression resistance, compression resilience and thickness loss. Results showed that the aerogel-encapsulated structure has significant effect on thermal insulation enhancement. A temperature gap of 1℃ to 1.5℃ was observed between aerogel-filled samples and regular ones. It is also found that nonwoven fabrics with aerogel-filled voids generally have lower compression resistance than regular nonwovens, samples with air-filled voids and aerogel-filled voids are observed to recover compression to a lower extent than regular samples. Nonwoven based aerogel-encapsulated composites exhibit lower thickness loss in comparison with untreated composites. The findings in this study can be used for further research in aerogel-encapsulated composites. [ABSTRACT FROM AUTHOR]

Published

2018

25. Acoustic evaluation of Struto nonwovens and their relationship with thermal properties.

Author

Yang, Tao, Xiong, Xiaoman, Mishra, Rajesh, Novák, Jan, and Militký, Jiří

Subjects

NONWOVEN textiles, THERMAL properties of textiles, ABSORPTION of sound, THERMAL analysis, NOISE control, THERMAL conductivity

Abstract

This paper presents an experimental investigation on the sound absorption behavior and thermal properties of Struto nonwovens by establishing relationship between these properties. Seven Struto nonwoven fabrics were selected to examine the noise reduction coefficient (NRC) and average values of sound absorption coefficients (α¯) as well as thermal properties, including thermal conductivity and thermal resistance. The Brüel and Kjær impedance tube instrument and Alambeta were used for the evaluation of acoustic and thermal properties, respectively. The influence of structural parameters on acoustic and thermal properties of Struto nonwovens were investigated and analyzed. The results showed that Struto nonwovens with higher thickness, finer fibers and higher fabric grams per square meter can provide better sound absorption performance. The effect of specific airflow resistance on sound absorption performance was also investigated. It is observed that sound absorption performance has a strong correlation with specific airflow resistance. The effect of porosity on specific airflow resistance and thermal properties was studied in detail. The result indicated that porosity has a strong correlation with specific airflow resistance and thermal properties. It was also observed that sound absorption, the NRC and α¯ have an insignificant correlation with thermal conductivity, while they are strongly correlated with thermal resistance. The correlation coefficient of the NRC with thermal resistance is 0.9835, indicating that the NRC is directly proportional to the thermal resistance of Struto nonwovens. [ABSTRACT FROM AUTHOR]

Published

2018

26. Investigation on laser engraving based application of silica aerogel into nonwovens.

Author

Xiong, Xiaoman, Yang, Tao, Mishra, Rajesh, Wiener, Jakub, and Militký, Jiří

Abstract

In this work, a new approach to apply silica aerogel into nonwoven textiles by using laser engraving and laminating technique was proposed. Thermal performance of the prepared composites were characterized in terms of infrared thermal images, maximum heat flux and heat retention ability. Results showed that in comparison to regular composites the air pockets lead to 0.5°C lower temperature on the fabric surface, and the aerogel-encapsulated structure results in a decrease of 1.04-1.47°C in the fabric temperature. It was also noticed the aerogel-encapsulated composites have slightly lower q value and a thermal feeling, however, samples with air pockets showed increased value in q, and the increasing rate was strongly related to the composites thickness. Composites with air pockets exhibited better ability to retain heat, the highest heat retention ability was observed from composites with aerogel-encapsulated structure. [ABSTRACT FROM AUTHOR]

Published

2017

27. Analysis of the influence of pyroptosis-related genes on molecular characteristics in patients with acute myocardial infarction.

Author

Wu, Huan, Xiong, Xiaoman, CUI, Xueying, Xiong, Jianlong, Zhang, Yan, Xiang, Liubo, and Xu, TAO

Published

2023

28. Preparation and Characterization of Electrosprayed Aerogel/Polytetrafluoroethylene Microporous Materials.

Author

Xiong, Xiaoman, Venkataraman, Mohanapriya, Yang, Tao, Militký, Jiří, and Wiener, Jakub

Subjects

*AEROGELS, *THERMAL conductivity, *POLYTEF, *VAPOR barriers, *AERODYNAMIC heating, *PARTICLE size distribution

Abstract

This paper presents the preparation of aerogel/polytetrafluoroethylene (PTFE) microporous materials via needleless electrospray technique, by using an aqueous dispersion of polytetrafluoroethylene as the basic spinning liquid. Different contents of aerogel powders were applied to the spinning liquid for electrospraying to investigate the effect on the structural characteristics and various properties of the materials. Cross-section, surface morphology, and particle size distribution of the electrosprayed materials were examined. Surface roughness, hydrophobicity, and thermal conductivity were evaluated and discussed. The results showed that the electrosprayed aerogel/PTFE layers were compact and disordered stacking structures composed of spherical particles with a rough surface. As the aerogel content increased, the electrosprayed materials demonstrated increased surface roughness and improved surface hydrophobicity with a contact angle up to 147.88°. In addition, the successful achievement of thermal conductivity as low as 0.024 (W m−1 K−1) indicated a superior ability of the prepared aerogel/PTFE composites to prevent heat transfer. This study contributes to the field of development of aerogel/PTFE composites via electrospray technique, providing enhanced final performance for potential use as thermal and moisture barriers in textiles or electronic devices. [ABSTRACT FROM AUTHOR]

Published

2022

29. Advances in nanomaterials as exceptional fillers to reinforce carbon fiber‐reinforced polymers composites and their emerging applications.

Author

Luo, Yuxin, Shi, Zhicheng, Qiao, Sijie, Tong, Aixin, Liao, Xiaohong, Zhang, Tongrui, Bai, Jie, Xu, Chao, Xiong, Xiaoman, Chen, Fengxiang, and Xu, Weilin

Subjects

*FIBROUS composites, *CHEMICAL stability, *AUTOMOBILE industry, *NANOSTRUCTURED materials, *ENERGY industries

Abstract

Highlights Carbon fiber reinforced polymer (CFRP) composites exhibit excellent characteristics such as light weight, high specific strength, specific stiffness, and chemical stability, making them customizable to meet the specific demands of various sectors such as the automotive, aerospace, defense, biomedical, and energy industries. However, the inert surface of carbon fibers (CFs) results in a poor interface compatibility with polymer matrices, leading to numerous interfacial defects and pores in prepared CFRP composites. These drawbacks significantly limit the application of CFRP composites in high‐end fields. The higher surface area and smaller size of nanomaterials provide multiple advantages for high‐performance CFRP composites that enhance the mechanical properties, impact resistance and interface adhesion between the fiber and the matrix. Hence, this review firstly summarizes the interfacial behavior and interface enhancement mechanisms for CFRP composites. Subsequently, we comprehensively review the recent advances in various nanomaterials‐modified CFRP composites, including carbon‐based nanoparticles, silicon‐based nanomaterials and metal nanomaterials, et al. Besides, we also present the applications of CFRP in emerging fields, such as military, aerospace, automotive, sports equipment, and medical, etc. Finally, we also prospected the challenges and future development trends of CFRP composites, aiming to provide new ideas and insights for future research on nanomaterial modifications and promote the development of high‐performance CFRP composites. The interface reinforced theory of CFRP is comprehensively summarized. Different types of nanoparticles that can be used for reinforcement in CFRP composites and nanomaterials modification methods are reviewed. Application of CFRP composites in various fields is presented. Challenges and future development directions of preparation of high‐performance CFRP composites are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

30. Sound Absorption Properties of Natural Fibers: A Review.

Author

Yang, Tao, Hu, Lizhu, Xiong, Xiaoman, Petrů, Michal, Noman, Muhammad Tayyab, Mishra, Rajesh, and Militký, Jiří

Abstract

In recent years, in an attempt to substitute the conventional synthetic sound absorption material, natural fibers and their sound absorption properties have been increasingly studied. This is due to the fact that conventional synthetic fiber has potential health risks for human beings and significant environmental impact. In this review, existing and newly emerging natural fiber sound absorbers are summarized and highlighted in three categories: raw material, fiber assembly and composite. The sound absorption mechanism, several widely used prediction models and the popular acoustic characterization methods are presented. The comparison of sound absorption properties between some natural sound absorbers and glass fiber is conducted in two groups, i.e., thin material and thick material. It is found that many natural fibers have comparable sound absorption performance, some of them can be the ideal alternatives to glass fiber, such as kapok fiber, pineapple-leaf fiber and hemp fiber. Last, the conclusion part of this review gives an outlook regarding the promotion of the commercial use of natural fiber by means of theoretical study, efficient and environmentally friendly pretreatment and Life Cycle Assessment. [ABSTRACT FROM AUTHOR]

Published

2020

31. Transport Properties of Electro-Sprayed Polytetrafluoroethylene Fibrous Layer Filled with Aerogels/Phase Change Materials.

Author

Xiong, Xiaoman, Venkataraman, Mohanapriya, Yang, Tao, Kucerova, Klara, Militký, Jiří, Yang, Kai, Zhu, Guocheng, and Yao, Juming

Subjects

*PHASE transitions, *AEROGELS, *POLYTEF, *HEAT transfer, *PARTICLE size distribution

Abstract

This work is the first attempt to prepare microporous polytetrafluoroethylene (PTFE) fibrous layers embedded with aerogels/phase change materials. For preparation of this layer, the needle-less electrospray technology of water dispersion of individual components is used. Microstructure characteristics, including surface morphology and particle size distribution, and various properties of the prepared materials were investigated and explained. Transport performance of the fibrous layers embedded with aerogels/phase change materials, such as the transmission of heat, air, and water vapor was evaluated and discussed in details. It was found that the electro-sprayed materials composed by spherical particles with rough surface had compact disordered stacking structure. Aerogels and phase change materials (PCMs) play different roles in determining structural parameters and transport properties of the materials. Those parameters and properties could be flexibly adjusted by optimizing the spinning parameters, changing the content or proportion of the fillers to meet specific requirements. [ABSTRACT FROM AUTHOR]

Published

2020

32. Characterization on Polyester Fibrous Panels and Their Homogeneity Assessment.

Author

Yang, Tao, Saati, Ferina, Groby, Jean-Philippe, Xiong, Xiaoman, Petrů, Michal, Mishra, Rajesh, Militký, Jiří, and Marburg, Steffen

Subjects

POLYESTERS, SOUND energy, REVERBERATION time, AUTOMOTIVE engineering, HOMOGENEITY

Abstract

Nowadays, fibrous polyester materials are becoming one of the most important alternatives for controlling reverberation time by absorbing unwanted sound energy in the automobile and construction fields. Thus, it is worthy and meaningful to characterize their acoustic behavior. To do so, non-acoustic parameters, such as tortuosity, viscous and thermal characteristic lengths and thermal permeability, must be determined. Representative panels of polyester fibrous material manufactured by perpendicular laying technology are thus tested via the Bayesian reconstruction procedure. The estimated porosity and airflow resistivity are found in good agreement with those tested via direct measurements. In addition, the homogeneity of polyester fibrous panels was characterized by investigating the mean relative differences of inferred non-acoustic parameters from the direct and reverse orientation measurements. Some parameters, such as tortuosity, porosity and airflow resistivity, exhibit very low relative differences. It is found that most of the panels can be assumed homogeneous along with the panel thickness, the slight inhomogeneity mostly affecting the thermal characteristic length. [ABSTRACT FROM AUTHOR]

Published

2020

33. Theoretical and Experimental Studies on Thermal Properties of Polyester Nonwoven Fibrous Material.

Author

Yang, Tao, Xiong, Xiaoman, Petrů, Michal, Tan, Xiaodong, Kaneko, Hiroki, Militký, Jiří, and Sakuma, Atsushi

Abstract

Polyester nonwoven fibrous material is widely used in construction and automobile industries for thermal insulation purposes. It is worthy and meaningful to understand the effect of structural parameters on the thermal property. Fiber orientation, as one of the most vital parameters, has a significant effect on thermal property. However, there has been little quantitative analysis focusing on this aspect. This paper theoretically and experimentally analyzes the thermal conductivity of samples with varying fiber orientation. Existing models were selected to predict the thermal conductivity of polyester nonwoven samples. Two different apparatus were applied to carry out the experimental measurements. The relative differences between the predicted and measured results were compared. One commonly used model was modified for accurate prediction. It was shown that some existing models under- or overestimate the thermal conductivity compared to the measured values. The results indicate that the modified model can accurately predict the thermal conductivity of polyester nonwoven materials within a 0.2% relative difference. [ABSTRACT FROM AUTHOR]

Published

2020

34. Preparation of Electrosprayed, Microporous Particle Filled Layers.

Author

Venkataraman, Mohanapriya, Yang, Kai, Xiong, Xiaoman, Militky, Jiri, Kremenakova, Dana, Zhu, Guocheng, Yao, Juming, Wang, Yan, and Zhang, Guoqing

Subjects

ELECTRICAL resistivity, COMPOSITION of water, POLYMER solutions, HYDROPHOBIC interactions, PARTICULATE matter

Abstract

Polytetrafluoroethylene (PTFE) is a synthetic fluoropolymer known for its excellent hydrophobic properties. In this work, samples from PTFE dispersions with different combinations of water and carbon microparticles were prepared using an electrospraying method. The morphologies and sizes of carbon particles were investigated and the properties of layers including roughness, hydrophobicity and electrical resistivity were investigated. The non-conductive carbon microparticles were selected as a model particle to check the compatibility and electrospraying ability, and it had no effect on the hydrophobic and electrical properties. Carbon microparticles in polymer solution increased the degree of ionization and was found to be beneficial for the shape control of materials. The results showed that PTFE dispersion with the composition of water and carbon microparticles produced fine sphere particles and the layer fabricated with increased roughness. It was also found that the electrical resistivity and hydrophobicity of all the layers comparatively increased. The fabricated microporous layers can be used in various applications like interlining layer in multilayer textile sandwiches. [ABSTRACT FROM AUTHOR]

Published

2020

35. Preparation and Characterization of Electrosprayed Aerogel/Polytetrafluoroethylene Microporous Materials.

Author

Xiong X, Venkataraman M, Yang T, Militký J, and Wiener J

Abstract

This paper presents the preparation of aerogel/polytetrafluoroethylene (PTFE) microporous materials via needleless electrospray technique, by using an aqueous dispersion of polytetrafluoroethylene as the basic spinning liquid. Different contents of aerogel powders were applied to the spinning liquid for electrospraying to investigate the effect on the structural characteristics and various properties of the materials. Cross-section, surface morphology, and particle size distribution of the electrosprayed materials were examined. Surface roughness, hydrophobicity, and thermal conductivity were evaluated and discussed. The results showed that the electrosprayed aerogel/PTFE layers were compact and disordered stacking structures composed of spherical particles with a rough surface. As the aerogel content increased, the electrosprayed materials demonstrated increased surface roughness and improved surface hydrophobicity with a contact angle up to 147.88°. In addition, the successful achievement of thermal conductivity as low as 0.024 (W m -1 K -1 ) indicated a superior ability of the prepared aerogel/PTFE composites to prevent heat transfer. This study contributes to the field of development of aerogel/PTFE composites via electrospray technique, providing enhanced final performance for potential use as thermal and moisture barriers in textiles or electronic devices.

Published

2021

36. Cardiac biomarkers, cardiac injury, and comorbidities associated with severe illness and mortality in coronavirus disease 2019 (COVID-19): A systematic review and meta-analysis.

Author

Zhu Z, Wang M, Lin W, Cai Q, Zhang L, Chen D, Liu F, Xiong X, Chu J, Peng J, and Chen K

Subjects

Biomarkers, Creatine Kinase, MB Form, Humans, SARS-CoV-2, Troponin I, COVID-19

Abstract

Aims: To explore the correlation between cardiac-related comorbidities, cardiac biomarkers, acute myocardial injury, and severity level, outcomes in COVID-19 patients., Method: Pubmed, Web of Science, Embase, CNKI, VIP, Wanfang, Cochrane Library databases, medRxiv, and Sinomed were reviewed systemically. Various types of clinical research reporting cardiac-related comorbidities, cardiac biomarkers including lactate dehydrogenase (LDH), troponin I (TnI), high sensitivity troponin I (hs-TnI), creatine kinase (CK), creatine kinase-MB (CK-MB), myoglobin (Myo), N-terminal pro-b-type natriuretic peptide (NT-proBNP) and acute cardiac injury grouped by severity of COVID-19 were included. Outcome measures were events and total sample size for comorbidities, acute cardiac injury, and laboratory parameters of these biomarkers. The study was performed with Stata version 15.1., Results: Seventy studies, with a total of 15,354 cases were identified. The results showed that COVID-19's severity was related to cardiovascular disease. Similar odds ratios (ORs) were achieved in hypertension except for severe versus critical group (OR = 1.406; 95% CI, 0.942-2.097; p = .095). The relative risk (RR) of acute cardiac injury is 7.01 (95% CI, 5.64-8.71) in non-survivor cases. When compared with the different severity of cardiac biomarkers, the pool OR of CK, CK-MB, TnI, Myo and LDH were 2.683 (95% CI, 0.83-8.671; p = .106; I 2  = 0%), 2.263 (95% CI, 0.939-5.457; p = .069), 1.242 (95% CI, 0.628-2.457; p = .534), 1.756 (95% CI, 0.608-5.071; p = .298; I 2  = 42.3%), 1.387 (95% CI, 0.707-2.721;  p = .341; I 2  = 0%) in the critical versus severe group, whose trends were not similar to other groups. The standard mean differences (SMD) of CK and TnI in the critical versus severe group were 0.09 (95% CI, -0.33 to 0.50; p = .685; I 2  = 65.2%), 0.478 (95% CI, -0.183 to 1.138; p = .156; I 2  = 76.7%), which means no difference was observed in the serum level of these indicators., Conclusion: Most of the findings clearly indicate that hypertension, cardiovascular disease, acute cardiac injury, and related laboratory indicators are associated with the severity of COVID-19. What is now needed are cross-national prospectively designed observational or clinical trials that will help improve the certainty of the available evidence and treatment decisions for patients., (© 2021 The Authors. Immunity, Inflammation and Disease published by John Wiley & Sons Ltd.)

Published

2021