Erscheinungsdatum: 10/2010, Medium: Buch, Einband: Gebunden, Titel: Handbook of Antiblocking, Release, and Slip Additives, Auflage: Revised, Autor: Wypych, George, Verlag: CHEMTEC PUB, Sprache: Englisch, Schlagworte: Technology & Industrial Arts // SCIENCE // Chemistry // Industrial & Technical // TECHNOLOGY & ENGINEERING // Materials Science // Textiles & Polymers // Chemie, Rubrik: Chemische Technik, Seiten: 640, Gewicht: 689 gr, Verkäufer: averdo
Erscheinungsdatum: 12/2002, Medium: Buch, Einband: Gebunden, Titel: Nonwoven Fabrics, Titelzusatz: Raw Materials, Manufacture, Applications, Characteristics, Redaktion: Albrecht, Wilhelm // Fuchs, Hilmar // Kittelbaum, Walter, Verlag: Wiley VCH Verlag GmbH // Wiley-VCH, Sprache: Englisch, Schlagworte: Chemie // Technik // Werkstoffe // Berufe // Industrie // Chemische Industrie // Arbeitsstoff // Material // Werkstoff // SCIENCE // Chemistry // Industrial & Technical // TECHNOLOGY & ENGINEERING // Textiles & Polymers // Industrielle Chemie und Chemietechnologie, Rubrik: Chemische Technik, Seiten: 750, Abbildungen: 550 Abb., Gewicht: 1373 gr, Verkäufer: averdo
Erscheinungsdatum: 30.04.2014, Medium: Buch, Einband: Gebunden, Titel: Porous Materials for Carbon Dioxide Capture, Auflage: 2014, Redaktion: Lu, An-Hui // Dai, Sheng, Verlag: Springer-Verlag GmbH // Springer Berlin, Sprache: Englisch, Schlagworte: Katalyse // Katalysator // Biokatalyse // Biokatalysator // Nanotechnologie // Technologie // Polymere // Polymerisation // Chemie // organisch // Organische Chemie // physikalisch // Physik // Physikalische Chemie // Klima // Meteorologie // Witterung // Energie // Erneuerbare Energie // Energiewirtschaft // Regenerative Energie // Erde // Planet // Geowissenschaft // SCIENCE // Chemistry // Industrial & Technical // Energy // Earth Sciences // Meteorology & Climatology // TECHNOLOGY & ENGINEERING // Nanotechnology & MEMS // Textiles & Polymers // Meteorologie und Klimatologie // Klimaforschung // Alternative und erneuerbare Energiequellen und // technik, Rubrik: Wärme- // Energie-, Kraftwerktechnik, Seiten: 245, Abbildungen: 88 schwarz-weiße und 68 farbige Abbildungen, Bibliographie, Herkunft: NIEDERLANDE (NL), Reihe: Green Chemistry and Sustainable Technology, Gewicht: 525 gr, Verkäufer: averdo
Assos hK_sturmNuss Rain Shell Half KnickerAssos' highly technical hK_sturmNuss Rain Shell Half Knicker is perfectly tailored to fit when on the bike and using five pattern pieces, three different textiles and nine components it protects you from harsh weather conditions as you ride.Thise areas most exposed to the rain use TRITON 2019 to prevent water from getting in while the side panels use ultralight and four-way stretch TRITON 0017 to give you total freedom of movement when pedalling. Taped seams are used only where necessary, minimising bulk so you're not weigh down.The Triton fabrics are waterproof fabrics developed by the ASSOS textile laboratory, with a high degree of water protection while remaining incredibly breathable. TRITON fabrics are able to adapt to changes in ambient temperature thanks to “flexible membrane barrier technology.” When the temperature is low, the membrane reduces permeability, helping to retain body heat. As the temperature inside the garment rises, the membrane’s pores open to accelerate vapour transfer, leaving you dry and comfortable. The hK_sturmNuss Rain Shell Half Knickers ensure incredible comfort and protection allowing you to keep riding through the very worst that mother nature can throw your way. Features:Material: 62% Polyamide, 25% Elastane, 14% PolyurethaneIntelligently engineered, cycling-specific raingearSiliconized calf gripper, patterned to fall just below the knee cap.Taped seams, where it makes sense, to improve water repellency.Comprises five pattern pieces, three fabrics and nine components.Shaped to fit the body in the cycling position, ensuring freedom of movement in and out of the saddleIncorporates two versions of TRITON fabric, a proprietary ASSOS textile laboratory creationReacts to changes in body temperature; permeability increases as temperature rises.Ultra CompactRelieves unnecessary abdominal pressure with unique waistband construction.Buy Assos Clothing from Chain Reaction Cycles, the World's Largest Online Bike Store.
An important and growing part of the textile industry consists of the medical, healthcare and hygiene sectors. The extend of the growth is due to the constant improvements and innovations in both textile technology and medical procedures. Textile materials have been indispensable in the medical area. It has helped the medical world in every form and shape. Staple fibres are used for cleaning wounds, bandages for covering wounds, sutures are indispensable for surgery, plasters for joining bone fractures and knitted vascular grafts widely used to replace arteries. There has been a steady development in these textiles used for medical purposes, are more commonly termed as "medical textiles". Medical textiles are a major thrust area within the technical textile industry and the range of applications continue to bloom and increase its diversity with every new development. In the past decades, more and more efforts have been expanded on the development of new materials for the use as surgical sutures, especially absorbable sutures with satisfactory tensile strength and excellent biocompatibility. The degradation behaviour of suture materials is very important.
Braiding is the process of interlacing three or more threads or yarns in a diagonal direction to the product axis in order to obtain thicker, wider or stronger textiles or, in the case of overbraiding, in order to cover a profile. Braids are becoming the reinforcement of choice in composite manufacturing, and have found a range of technical applications in fields including medicine, candles, transport and aerospace. Building on the information provided in Prof. Kyosev's previous book, Braiding Technology for Textiles , this important title covers advanced technologies and new developments for the manufacture, applications and modelling of braided products.Part One covers the braiding of three-dimensional profiles, and includes a detailed overview of three-dimensional braiding technologies as well as chapters devoted to specific kinds of 3D braiding. Part Two addresses specialist braiding techniques and applications, and includes chapters reviewing the use of braids for medical textiles and candles. Part Three focuses on braiding techniques for ropes and Part Four reviews braiding for composites. The final part of the book considers modelling and simulation, and covers topics including overbraiding simulation, Finite Element Method (FEM) modelling and geometrical modelling.Covers advanced braiding techniques, technical applications, and modelling and simulation of braided textiles.Focused on the needs of the textile industry by offering suitable breadth and depth of coverage of a range of braiding manufacturing technology, applications and modelling techniques in a single volume.Written by an eminent team of authors, composed of leading scientists and developers in the field who have a wealth of relevant, first-hand experience in braiding, and edited by a high-profile editor who is an expert in his field.
Three dimensional voluminous nonwovens are a valuable and new generation source to replace the less-recyclable and less environment friendly polyurethane foams with the fulfilment of various technical, functional, design and aesthetic requirements for automotive textiles. The book describes about various 3D voluminous nonwovens structures and is focused on vertical laid Wavemaker technology based nonwovens. In the case the manufacturing technique to produce Wavemaker nonwovens, effect of fiber fineness, structural parameters, process parameters and different type of feeding web structures on the various properties of the Wavemaker nonwovens for car seat and headliner cushioning materials are illustrated. The book also purposes the evolution of context aware application to determine what to test, how to test and the appropriate metrics to use.
The industrial sector is very promising for the use of solar thermal technology, since it accounts for a large share of the total final energy consumption (e.g. 27 % in Germany in 2010) and it predominantly uses the consumed energy as thermal energy (74 % in Germany in 2010). In order to develop this area of application, it is necessary to understand which industrial sectors have the highest potential, which processes within these sectors are most suitable for the integration of solar heat as well as to quantify the possible contribution to the industrial heat demand. For this thesis, the industrial heat consumption in Germany is analyzed, which leads to the selection of the 11 most promising sectors within industry. These are Chemicals, Food and beverages, Motor vehicles, Paper, Fabricated metal, Machinery and equipment, Rubber and plastic, Electrical equipment, Textiles, Printing and Wood. The theoretical potential of solar heat for industrial processes below 300 °C in Germany adds up to 134 TWh per year, the technical potential (considering efficiency measures, limited roof area and a solar fraction) being 16 TWh per year or 3.4 % of the overall industrial heat demand.Solar thermal systems can achieve higher system yields in industrial applications compared to domestic ones. At the same time, systems can be more complex in industrial applications. In order to design and operate solar process heat systems efficiently and to exploit the large potential, possible faults of such systems and their impact have to be evaluated. In this thesis, an implemented solar process heat system is methodically analyzed based on measurements and simulations with a validated model. Several faults are identified and their influence, as well as the influence of a reduced load on the system yield is evaluated. The analysis shows that a reduced load is most influential. Further, the most important impact factors on the system performance are identified: the collector parameters (?0, a1) and load characteristics (mass flow, temperature). The design of solar process heat systems is in many cases very demanding, hence costly. This high effort is a major barrier for a further development of solar heat for industrial applications. The decision to install solar thermal systems is in most cases based on solar heat generation cost. Collector field and heat store size are the most important figures for the estimation of the overall cost of a solar thermal system. Therefore, a simple approach for dimensioning the collector field and heat store is developed in this thesis in order to enable manufacturers and planners on one hand and costumers on the other hand to make a decision in favor or against a solar process heat system. In addition to investment cost, the specific system yield, which is determined for selected process heat applications in this thesis, is necessary to calculate solar heat generation cost. Finally, indications on the necessary accuracy of the load profile are provided to help to reduce effort in the design phase.
The technical importance of flexible composite structures needs no emphasis nor has there been any lack of material descriptive of their manufacture or properties. The starting points of such descriptions have invariably been from the viewpoint of the rubber industry and the presence of a suitable textile has been taken for granted, its strength properties indicated and the technological content confined to the manufacturing process within the rubber industry. An attempt is made here to work from the textile outwards. Industrial fabrics are far heavier than garment textiles, are not produced in the same bulk quantities and need to be specially constructed to provide the balance of properties which will combine with those of the rubber to give the final. product. The most important composite structure formed from textiles and rubber is, of course, the pneumatic tyre. It may therefore seem strange that no chapter deals with this. The reason is quite simple. To deal with the structure and design of the pneumatic tyre in a similar depth of detail as is done here for conveyor or power transmission belting, or hose, would require disproportionate space, in fact, a second volume equal in size to the present one. This book discusses from the textile viewpoint the various reinforced rubber structures used industrially with the exception of the tyre. These other uses of industrial fabrics can be discussed in adequate detail and cover the whole range of the technology involved in the space available in the one volume.