Your search keyword '"Airlaid"' showing total 9 results

1. Development of Airlaid Non-woven Panels for Building’s Thermal Insulation

Author

Ayadi, Melek, Zouari, Riadh, Segovia, Cesar, Baffoun, Ayda, Msahli, Slah, Brosse, Nicolas, Ghosh, Arindam, Series Editor, Chua, Daniel, Series Editor, de Souza, Flavio Leandro, Series Editor, Aktas, Oral Cenk, Series Editor, Han, Yafang, Series Editor, Gong, Jianghong, Series Editor, Jawaid, Mohammad, Series Editor, Msahli, Slah, editor, and Debbabi, Faten, editor

Published

2022

2. Spray and foam application of chemical binders to pulp fiber airlaids.

Author

Paunonen, Sara, Hjelt, Tuomo, Kamppuri, Taina, and Kiiskinen, Harri

Abstract

Pulp fiber airlaid nonwovens were bonded with three binder formulations in a spray and foam process. The binders were: a commercial acrylic dispersion binder, a commercial bio-containing acrylic binder; and a citric acid-carboxymethyl cellulose mixture (CACMC) (1:1 by-weight). The binder solutions were applied at same concentrations onto A4-size airlaid sheets (80 gsm) under a vacuum with 2-sided spraying and 1-sided foam coating. The sheet structure, dry and wet tensile properties, and total absorption capacity were compared. The foam application densified and bulk bonded the sheets, whereas the spray application induced surface bonding. These factors fundamentally influenced the measured sheet properties. The dry tensile strength was linearly correlated with the relatively low binder dosages. The CACMC binder exposed the differences in the binder application processes well, and lead to strong sheets with small elongation and highly application method-dependent absorption capacity compared to acrylic binders. [ABSTRACT FROM AUTHOR]

Published

2022

3. Assessing the structural, mechanical and dispersible characteristics of flushable nonwovens.

Author

Atasağun, Hande G and Bhat, Gajanan S

Subjects

OBEDIENCE (Law), ENVIRONMENTAL protection, GOVERNMENT regulation, PRODUCTION methods, RAW materials

Abstract

Flushable wipes have become popular among consumers who worry about environmental problems the world confronts today. However, whether these wipes have a positive effect on environmental protection is contradictory because of the lack of government regulations and legal obligations. Starting from this point, in this study, we characterized commercially available flushable products, which were manufactured from various raw materials by different production methods, in order to understand the relationship between their structure and performance properties. The results showed that production technology had a significant effect on the structural, mechanical, and dispersible properties of nonwovens. The disintegration percentage of nonwovens was inversely related to their wet strength. The findings of this study will be helpful in the design of new flushable nonwovens for improved wet strength and dispersibility performance. [ABSTRACT FROM AUTHOR]

Published

2020

4. Airlaid nonwoven panels for use as structural thermal insulation.

Author

Cerkez, I., Kocer, H. B., and Broughton, R. M.

Subjects

THERMAL insulation, GLASS fibers, POLYESTER fibers, MECHANICAL behavior of materials, FLEXURAL strength

Abstract

Thermal-bonded airlaid nonwoven webs consisting of fiber glass and polyester bicomponent fibers were manufactured, and then multilayer webs were formed into composite panels using compression molding technique. The consolidation process was optimized and the effect of bulk density on air permeabilites, mechanical properties, and thermal resistance was studied. Increasing binder amount and bulk density improved the flexural and tensile strength. Thermal resistance of the panels were found to be very dependent on the bulk density such that the resistance increased exponentially with an initial increase in density, then leveled off and decreased linearly with further increment in density. Depending on the composition and bulk density, the panels provided thermal resistance between 0.52 and 0.88 Km2/W, tensile strength between 2 and 7 MPa, and flexural strength between 600 and 3500 kPa. The findings revealed that airlaid nonwoven panels can be designed to use as structural thermal insulation materials in constructions. [ABSTRACT FROM PUBLISHER]

Published

2018

5. Spray and foam application of chemical binders to pulp fiber airlaids

Author

Sara Paunonen, Tuomo Hjelt, Taina Kamppuri, and Harri Kiiskinen

Subjects

mechanical sheet properties, sheet structure, General Materials Science, Airlaid, bonding, biomaterials

Abstract

Pulp fiber airlaid nonwovens were bonded with three binder formulations in a spray and foam process. The binders were: a commercial acrylic dispersion binder, a commercial bio-containing acrylic binder; and a citric acid-carboxymethyl cellulose mixture (CACMC) (1:1 by-weight). The binder solutions were applied at same concentrations onto A4-size airlaid sheets (80 gsm) under a vacuum with 2-sided spraying and 1-sided foam coating. The sheet structure, dry and wet tensile properties, and total absorption capacity were compared. The foam application densified and bulk bonded the sheets, whereas the spray application induced surface bonding. These factors fundamentally influenced the measured sheet properties. The dry tensile strength was linearly correlated with the relatively low binder dosages. The CACMC binder exposed the differences in the binder application processes well, and lead to strong sheets with small elongation and highly application method-dependent absorption capacity compared to acrylic binders.

Published

2022

6. Method development for producing napkins and femcare absorbent cores by using an airlaid former

Author

Kilegran, Linnea and Kilegran, Linnea

Abstract

Fluffmassa är ett förnybart material bestående av cellulosafiber som utvinns under massakokning. Dessa fiber används för att tillverka olika absorberande produkter som till exempel servetter. Fluffmassa används även för att tillverka absorptionskärnor i damhygienprodukter, inkontinensprodukter och blöjor. Vissa av dessa absorptionskärnor (speciellt i ultratunna bindor) tillverkas med airlaid. Airlaid är en tillverkingsteknik som ger fiberstrukturer med slumpmässig orientering genom att applicera ett undertryck. Syftet med detta examensarbete var att utveckla metoder för att tillverka servetter och absorptionskärnor till damhygienprodukter i laboratoriemiljö genom att använda en airlaid maskin i laboratorieskala. Detta utfördes genom att analysera viktiga egenskaper som exempelvis ytvikt, tjocklek, densitet, böjlängd och förmågan att absorbera vätska i kommersiella servetter och absorptionskärnor inom damhygien. Även dragprov och SEM-analys utfördes. Resultatet från dessa analyser användes som ett riktvärde under metodutvecklingen. Två metoder utvecklades - en för att tillverka en servettstruktur och en för att tillverka en absorptionskärna för damhygien. De olika tillverkningsstegen inkluderar defibrering, formering, pressning, prägling, latexsprayning samt härdning. Båda strukturerna tillverkades, och dess egenskaper analyserades och jämfördes med de kommersiella produkterna. Analyserna visade att de utvecklade metoderna genererade struktuer vars ytvikt stämde väl överrens med de kommersialla produkterna. Strukturerna var dock tjockare och hade en lägre densitet än de kommmersiella produkterna. Den minskade densiteten påverkade förmodligen resultatet från de andra analyserna som utfördes i detta projekt. Servettstrukturen hade en lägre böjlängd än de kommersiella servetterna och damhygienstrukturen hade bättre absorption än de kommersiella produkterna. Båda strukturerna hade en ytfinish som överensstämmde väl med de kommersiella produkterna. Dock visade SEM-anal, Fluff pulp is a renewable material consisting of pure cellulose fibers which are obtained during pulping. These fibers are commonly used to form Airlaid-nonwoven products such as napkins and wipes. Fluff pulp is also used in absorbent cores in femcare products, incontinence products and diapers. Some of these absorbent core structures (especially in ultrathin pads) are produced through airlaid. Airlaid is a manufacturing technique which forms a randomly oriented fiber structure by using an applied suction. This degree project aimed at developing methods for producing napkins and femcare absorbent cores on a laboratory scale by using an airlaid former. Important properties such as grammage, thickness, density, bending length and absorption capacity were therefore measured on commercial napkins and femcare absorbent cores. Other analyses which were performed include tensile testing and SEM. Findings from these analyses were then used as a target reference during the method development. Two methods were developed; one for producing a napkin structure and one for producing a femcare absorbent core structure. The different manufacturing steps included fiber defiberization, sample formation, pressing, embossing, latex spraying and curing. Napkin structures and femcare absorbent core structures were produced by using the developed methods, and their properties were analyzed and compared with the commercial products. Analysis showed that the developed methods generated structures with grammages that corresponded well with the grammages in the commercial products. However, both developed structures were thicker and had lower density than the commercial products. This decreased density probably influenced the results in other analyses performed in this project. The developed napkin structure had a shorter bending length compared to the commercial napkins and the developed femcare structure had a better absorption capacity compared to the commercial femcare absorbent cores.

Published

2020

7. Metodutveckling för att tillverka servetter och absorptionskärnor inom damhygien genom att använda en airlaid maskin

Author

Kilegran, Linnea

Subjects

thermofiber, absorbent core, airlaid, superabsorbent, Fluffmassa, Pappers-, massa- och fiberteknik, Fluff pulp, absorptionskärna, termofiber, Paper, Pulp and Fiber Technology, superabsorbent polymer

Abstract

Fluffmassa är ett förnybart material bestående av cellulosafiber som utvinns under massakokning. Dessa fiber används för att tillverka olika absorberande produkter som till exempel servetter. Fluffmassa används även för att tillverka absorptionskärnor i damhygienprodukter, inkontinensprodukter och blöjor. Vissa av dessa absorptionskärnor (speciellt i ultratunna bindor) tillverkas med airlaid. Airlaid är en tillverkingsteknik som ger fiberstrukturer med slumpmässig orientering genom att applicera ett undertryck. Syftet med detta examensarbete var att utveckla metoder för att tillverka servetter och absorptionskärnor till damhygienprodukter i laboratoriemiljö genom att använda en airlaid maskin i laboratorieskala. Detta utfördes genom att analysera viktiga egenskaper som exempelvis ytvikt, tjocklek, densitet, böjlängd och förmågan att absorbera vätska i kommersiella servetter och absorptionskärnor inom damhygien. Även dragprov och SEM-analys utfördes. Resultatet från dessa analyser användes som ett riktvärde under metodutvecklingen. Två metoder utvecklades - en för att tillverka en servettstruktur och en för att tillverka en absorptionskärna för damhygien. De olika tillverkningsstegen inkluderar defibrering, formering, pressning, prägling, latexsprayning samt härdning. Båda strukturerna tillverkades, och dess egenskaper analyserades och jämfördes med de kommersiella produkterna. Analyserna visade att de utvecklade metoderna genererade struktuer vars ytvikt stämde väl överrens med de kommersialla produkterna. Strukturerna var dock tjockare och hade en lägre densitet än de kommmersiella produkterna. Den minskade densiteten påverkade förmodligen resultatet från de andra analyserna som utfördes i detta projekt. Servettstrukturen hade en lägre böjlängd än de kommersiella servetterna och damhygienstrukturen hade bättre absorption än de kommersiella produkterna. Båda strukturerna hade en ytfinish som överensstämmde väl med de kommersiella produkterna. Dock visade SEM-analysen att latex saknades i mitten av de båda tillverkade strukturerna. Fluff pulp is a renewable material consisting of pure cellulose fibers which are obtained during pulping. These fibers are commonly used to form Airlaid-nonwoven products such as napkins and wipes. Fluff pulp is also used in absorbent cores in femcare products, incontinence products and diapers. Some of these absorbent core structures (especially in ultrathin pads) are produced through airlaid. Airlaid is a manufacturing technique which forms a randomly oriented fiber structure by using an applied suction. This degree project aimed at developing methods for producing napkins and femcare absorbent cores on a laboratory scale by using an airlaid former. Important properties such as grammage, thickness, density, bending length and absorption capacity were therefore measured on commercial napkins and femcare absorbent cores. Other analyses which were performed include tensile testing and SEM. Findings from these analyses were then used as a target reference during the method development. Two methods were developed; one for producing a napkin structure and one for producing a femcare absorbent core structure. The different manufacturing steps included fiber defiberization, sample formation, pressing, embossing, latex spraying and curing. Napkin structures and femcare absorbent core structures were produced by using the developed methods, and their properties were analyzed and compared with the commercial products. Analysis showed that the developed methods generated structures with grammages that corresponded well with the grammages in the commercial products. However, both developed structures were thicker and had lower density than the commercial products. This decreased density probably influenced the results in other analyses performed in this project. The developed napkin structure had a shorter bending length compared to the commercial napkins and the developed femcare structure had a better absorption capacity compared to the commercial femcare absorbent cores. Both developed structures obtained nice surface finish which corresponded well with the surface finish in the commercial products. However, SEM analysis indicated that no latex managed to reach the center in the developed structures.

Published

2020

8. Desarrollo y caracterización de no tejidos a partir de residuos de fibras textiles

Author

Díaz García, Pablo, Fages Santana, Eduardo, Universitat Politècnica de València. Departamento de Ingeniería Textil y Papelera - Departament d'Enginyeria Tèxtil i Paperera, Universitat Politècnica de València. Escuela Politécnica Superior de Alcoy - Escola Politècnica Superior d'Alcoi, Sempere Jaén, Francisco, Díaz García, Pablo, Fages Santana, Eduardo, Universitat Politècnica de València. Departamento de Ingeniería Textil y Papelera - Departament d'Enginyeria Tèxtil i Paperera, Universitat Politècnica de València. Escuela Politécnica Superior de Alcoy - Escola Politècnica Superior d'Alcoi, and Sempere Jaén, Francisco

Abstract

[ES] Con la ejecución de este trabajo final de master se pretende obtener no-tejidos a partir de residuos textiles tales como borra textil larga, residuo de fibra de aramida o poliéster. Previamente se describirán las especificaciones técnicas que deberá cumplir el producto obtenido, para dar respuestas a determinadas solicitudes. (aislamiento acústico, aislamiento térmico y calorimétrico ) Para ello, primero se realizará una investigación de las técnicas de obtención de los no-tejidos y se utilizará el equipo de Air Laid y la carda para el desarrollo de las muestras. Finalmente, los no-tejidos que se obtengan se caracterizarán en laboratorio para determinar el nivel de aislamiento acústico, aislamiento térmico y cono calorimétrico, y se analizarán los resultados obtenidos., [EN] With the execution of this project, the objective has been to obtain ¿nonwovens¿ from textile residues. Firstable, I have carried out an investigation of the techniques of obtaining the ¿nonwovens¿ and after this, I have used the Airlaid equipment for the development of the samples. Finally, It has been characterized the ¿nonwovens¿ obtained in the laboratory to determine the level of sound insulation, thermal insulation and fire behavior, and the results obtained will be analyzed.

Published

2019

9. Desarrollo y caracterización de no tejidos a partir de residuos de fibras textiles

Author

Sempere Jaén, Francisco

Subjects

Isolation, Residue, INGENIERIA TEXTIL Y PAPELERA, Máster Universitario en Ingeniería Textil-Màster Universitari en Enginyeria Tèxtil, Nonwoven, Aislamiento, Aramid, Aramida, No tejido, Residuos, Airlaid

Abstract

[ES] Con la ejecución de este trabajo final de master se pretende obtener no-tejidos a partir de residuos textiles tales como borra textil larga, residuo de fibra de aramida o poliéster. Previamente se describirán las especificaciones técnicas que deberá cumplir el producto obtenido, para dar respuestas a determinadas solicitudes. (aislamiento acústico, aislamiento térmico y calorimétrico ) Para ello, primero se realizará una investigación de las técnicas de obtención de los no-tejidos y se utilizará el equipo de Air Laid y la carda para el desarrollo de las muestras. Finalmente, los no-tejidos que se obtengan se caracterizarán en laboratorio para determinar el nivel de aislamiento acústico, aislamiento térmico y cono calorimétrico, y se analizarán los resultados obtenidos., [EN] With the execution of this project, the objective has been to obtain ¿nonwovens¿ from textile residues. Firstable, I have carried out an investigation of the techniques of obtaining the ¿nonwovens¿ and after this, I have used the Airlaid equipment for the development of the samples. Finally, It has been characterized the ¿nonwovens¿ obtained in the laboratory to determine the level of sound insulation, thermal insulation and fire behavior, and the results obtained will be analyzed.

Published

2019