Non Woven Fabrics Dealers in Colaba, Mumbai

A jacquard-woven fabric 44 inches wide{112 cms}, metallic motif adorns this organza fabric,silver floral & paisley -looks excellent,better than pictures. Background Color :greyish black,Motif Color Metallic silver,Length :1 yard + above-{continuous yardage available} Approximate Width 44 inches {112 cms}You can use this trim for your clothing, home décor, SCA, Renaissance Faire, LARP, belly dance, costume, craft, or other sewing project.

•  - WE DO OUR BEST TO DESCRIBE AN ITEM'S COLOR IN EACH DESCRIPTION WE WRITE. •  - WE HOLD EACH FABRIC TO THE WINDOW TO OBSERVE THE COLOR IN NATURAL LIGHT. •  - WE SCRATCH OUR HEADS SEARCHING FOR JUST THE RIGHT COLOR TERMS. •  - IN SPITE OF OUR BEST INTENTIONS, WE CAN NEVER GUARANTEE EXACT COLORS OR COLOR MATCHING WE CUSTOM MAKE YOUR COLOR/DESIGNS ASK FOR QUANTITY WE DO CUSTOM CURTAIN/BED SPREAD/BED SKIRT SHAMS ETC WE SELL SWATCHBrocade fabric ~ width 44"~ Bright Redx METTALIC gold color ~ very pretty .very nice feel and finish, looks better than pictures,great for victorian gowns and much more,the tradition of bringing silk to life brocade weaving, especially with gold and silver, has been an age-old tradition in india. there are two broad classes of brocades. brocades of pure silk or silk and cotton blends and zari brocades with gold and silver threads. the most important material in brocade weaving is silk. it facilitates lovely weaves, is durable, strong, fine and smooth. there are several varieties of raw silk of which the chief ones used for brocades are tanduri, banaka and mukta. tanduri is imported from malda and other places.

• Type: Non Woven Polypropylene Fabric
• Color: White
• Feature: Anti-Bacteria, Biodegradable, Moisture Proof, Recyclable, Security
• Width: 170MM
• Material: MELT BLOWN FABRIC
• Geotextile Type: POLYPROPELENE

Request to read the following details : Meltblown Non Woven FabricUSE: Middle Layer Face MasksBFE: 99.67%GSM : 25 gsm Colour : White Width : 175 MMCertificate and test report can be provided. 

• Technics : :
• Nonwoven: Brand
• :: FIL
• Origin: :
• Mumbai,India: Category
• :: Textile & Leather / Fabrics / Non-woven Cloth & Industrial Fabrics
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We are the leading exporters and supplier of this products.

Nakoda textiles a well established manufacturer and supplier of quality nonwoven interlining fabrics from india.

Nonwovens are unique engineered fabrics offering cost effective solutions for an increasingly wide variety of applications. A more formal definition of "nonwoven" by ISO 9092 is: A manufactured sheet, web or batt or directionally or randomly orientated fibres, bonded by friction, and/or cohesion and/or adhesion, excluding paper and products which are woven, knitted, tufted, stitchbonded incorparting binding yarns or filaments, or felted by wet milling, whether or not additionally needled. The fibres may be of natural or man-made origin and may be staple or continuous filaments. Nonwoven fabrics are broadly defined as sheet or web structures bonded together by entangling fiber or filaments (and by perforating films) mechanically, thermally or chemically. They are flat, porous sheets that are made directly from separate fibers or from molten plastic or plastic film. They are not made by weaving or knitting and do not require converting the fibers to yarn. Nonwoven fabrics are engineered fabrics that may be a limited life, single-use fabric or a very durable fabric. Nonwoven fabrics provide specific functions such as absorbency, liquid repellency, resilience, stretch, softness, strength, flame retardancy, washability, cushioning, filtering, bacterial barrier and sterility. These properties are combined to create the required functionality, while achieving a profitable balance between the expected product life and cost. They can mimic the appearance, texture and strength of a woven fabric and can be as bulky as the thickest paddings. In combination with other materials they provide a spectrum of products with diverse properties, and are used alone or as components of apparel, home furnishings, health care, engineering, industrial and consumer goods. “A nonwoven is a sheet of fibres, continuous filaments, or chopped yarns of any nature or origin, that have been formed into a web by any means, and bonded together by any means, with the exception of weaving or knitting. Felts obtained by wet milling are not nonwovens. Wetlaid webs are nonwovens provided they contain a minimum of 50% of man-made fibres or other fibres of non vegetable origin with a length to diameter ratio equals or superior to 300, or a minimum of 30% of man-made fibres with a length to diameter ratio equals or superior to 600, and a maximum apparent density of 0.40 g/cm³. Composite structures are considered nonwovens provided their mass is constituted of at least 50% of nonwoven as per to the above definitions, or if the nonwoven component plays a prevalent role.” How nonwovens are made? The production of nonwovens can be described as taking place in three stages, although modern technology allows an overlapping of the stages. In some cases all three stages can take place at the same time. The three stages are: Web formation Web Formation Nonwoven manufacture starts by the arrangement of fibres in a sheet or web. The fibres can be staple fibres packed in bales or filaments extruded form molten polymer granules. Four basic methods are used to form a web. The nonwoven are usually referred to by one of these technologies. Drylaid Airlaid Spunlaid/Meltblown Wetlaid Drylaid Carding is a mechanical process which starts with the opening of bales of fibres which are blended and conveyed to the next stage by air transport. The fibres are then combed into a web by carding machine, which is a rotating drum or series of drums covered in fine wires or teeth. The precise configuration of cards will depend on the fabric weight and fibre orientation required. The web can be parallel-laid, where most of the fibres are laid in the machine direction, or they can be random-laid. Typical parallel-laid carded webs result in good tensile strength, low elongation and low tear strength in the machine direction and the reverse in cross direction. Relative speeds and web composition can be varied to produce a wide range of properties. Airlaid The second method of drylaying is airlaying. In airlaying, the fibres, which can be very short, are fed into an air stream and from there to a moving belt or perforated drum, where they can form a randomly oriented web. Compared with carded webs, airlaid webs have a lower density, a greater softness and an absence of laminar structure. Airlaid webs offer great versatility in terms of the fibre blends that can be used. Spunlaid/Meltblown In this process polymer granules are melted and molten polymer is extruded through spinnerets. The continuous filaments are cooled and deposited on to a conveyer to form a uniform web. Some remaining temperature can cause filaments to adhere to one another, but this cannot be regarded as the principal method of bonding. The spunlaid process (sometimes known as spunbonded) has the advantage of giving nonwovens greater strength, but raw material flexibility is more restricted. Co-extrusion of second components is used in several spunlaid processes, usually to provide extra properties or bonding capabilities. In meltblown web formation, low viscosity polymers are extruded into a high velocity airstream on leaving the spinneret. This scatters the melt, solidifies it and breaks it up into a fibrous web. Wetlaid A dilute slurry of water and fibres is deposited on a moving wire screen and drained to form a web. The web is further dewatered, consolidated, by pressing between rollers and dried. Impregnation with binder is often included in a later stage of the process. Wetlaid web-forming allows a wide range of fibre orientations ranging from near random to near parallel. The strength of the random oriented web is rather similar in all directions in the plane of the fabric. A wide range of natural, mineral, synthetic and man-made fibres of varying lengths can be used. Web bonding Web Bonding Webs, other than spunlaid, have little strength in their unbonded form. The web must therefore be consolidated in some way. This is effected by bonding, a vital step in the production of nonwovens. The choice of method is at least as important to ultimate functional properties as the type of fibre in the web. There are three basic types of bonding: Chemical Thermal Mechanical Chemical Chemical bonding mainly refers to the application of a liquid based bonding agent to the web. Three groups of materials are commonly used as binders, acrylate polymers, styrene-butadiene copolymers and vinyl acetate copolymers. Water based systems are the most widely used but powdered adhesives, foam and in some cases organic solvent solutions are also found. There are many ways of applying the binder. It can be applied by impregnating, coating or spraying or intermittently, as in print bonding. Print bonding is used when specific patterns are required and where it is necessary to have the majority of fibres free of binder for functional reasons. Thermal This method uses the thermoplastic properties of certain synthetic fibres to form bonds under controlled heating. In some cases the web fibre itself can be used, but more often a low melt fibre or bicomponent fibre is introduced at the web formation stage to perform the binding function later in the process. There are several thermal bonding systems in use. Calendering uses heat and high pressure applied through rollers to weld the fibre webs together at speed. Through-air thermal bonding makes bulkier products by the overall bonding of a web containing low melting fibres. This takes place in a carefully controlled hot air stream. Drum and blanket systems apply pressure and heat to make products of average bulk. Sonic bonding takes place when the molecules of the fibres held under a patterned roller are excited by high frequency energy which produces internal heating and softening of the fibres. Mechanical In mechanical bonding the strengthening of the web is achieved by inter-fibre friction as a result of the physical entanglement of the fibres. There are two types of mechanical bonding: needlepunching and hydro-entanglement. Needlepunching can be used on most fibre types. Specially designed needles are pushed and pulled through the web to entangle the fibres. Webs of different characteristics can be needled together to produce a gradation of properties difficult to achieve by other means. Hydro-entanglement is mainly applied to carded or wetlaid webs and uses fine, high pressure jets of water to cause the fibres to interlace. Hydro-entanglement is sometimes known as spunlacing, as the arrangement of jets can give a wide variety of aesthetically pleasing effects. The water jet pressure used has a direct bearing on the strength of the web, but system design also plays a part. Finishing treatments Converting Nonwoven materials possess several important characteristics which permit handling at considerably higher speeds than conventional textile fabrics. Nonwovens can normally be cut in both the machine direction and cross-machine direction without unravelling of the edges. Nonwoven fabrics can also be engineered to facilitate high speed seaming and joining operations by means of adhesives, heat sealing or ultrasonic bonding techniques. Choosing the type of converting machine which is to be utilised to produce a given product involves not only the characteristics of the product itself and its raw materials, but also manufacturing requirements, philosophy and marketing considerations. The size and configuration of the product itself determines the basic type of machine. As these product, marketing and manufacturing considerations are evaluated, it is often necessary to make compromises and trade-offs to establish the best overall concept for production of a given product. Base web finishing Converting of nonwoven products often involves certain finishing operations which can be performed either inline with the converting machine or in an offline, roll-to-roll finishing operation. One common web finishing technique is to emboss the material for either decorative or functional purposes. Another common method of web finishing is to laminate a nonwoven with other materials to achieve a specific desired effect. Lamination with tissue can improve bulk, increase absorbency and reduce overall costs. Scrim may be laminated to nonwoven material as a means of greatly increasing the strength of the material. If barrier properties are required, lamination with a suitable barrier film may meet the requirements of the intended end use. Numerous printing processes are available as a mens of decorating a nonwoven material or for including identification or usage instructions on the finished product. Another finishing treatment is the coating of the nonwoven using one out of the wide range of techniques utilised to apply the coating. Furthermore a wide range of finishing treatments can be applied to nonwoven webs to change properties. Examples are aqueous fluid repellency, antimicrobial treatments, flame retardant and microencapsulation. The opportunity to combine different raw materials and different techniques accounts for the diversity of the industry and its products. This diversity is enhanced by the ability to engineer nonwovens to have specific properties and to perform specific tasks. RAW MATERIALS The three categories of raw materials used to produce a nonwoven fabric are: Fibers Binders Additives Fibers Fibers are the basic units of a nonwoven structure. Consequently, much of the utility properties and performance of a nonwoven is due to the fibers used. A fiber has been defined as any substance, natural or manmade, with a high length-to-width ratio and with suitable characteristics for being processed into a fabric. A wide range of fiber types, both synthetic and natural, have been employed in the production of nonwoven products. It is very likely that every fiber known to mankind has been used in a nonwoven structure at one time or another. However, commercially important nonwoven fabrics have been limited to relatively few fiber types, in view of the large that are available. The dominant fibers include polypropylene, polyester and rayon. Between them these three fiber types made up a substantial part of the overall nonwoven market for fibers. In Western Europe, for example, the three accounting for nearly 70% of staple fiber consumption by the nonwovens industry. Man-made fibres completely dominate nonwovens production, accounting for over 90% of total output. Man-made fibres fall into three classes, those made from natural polymers, those made from synthetic polymers and those made from inorganic materials. According to a study by Tecnon Ltd, the world usage of fibres in nonwovens production is: _ Polypropylene 63% _ Polyester 23% _ Viscose rayon 8% _ Acrylic 2% _ Polyamide 1.5% _ Other fibres 3% Over the years, the share of viscose rayon has increased due to its increased importance in the spunlace wipes market. However, recently, due to tremendous increase in price of viscose of fibre and its inability to be easily spunlaid or thermally bonded, there is a decrease in the consumption of viscose fibres. The solvent spun cellulosic fibre, Lyocell is becoming increasingly important in the nonwovens industry partly as a result of its absorbency and high wet strength. Polypropylene fibres are predominant in the nonwovens industry. Some of the reasons for this include: _ Low density and specific gravity enabling lightweight fabrics to be produced _ Low glass transition and melting temperature, which is attractive for thermal bonding. bonding _ Inherent hydrophobicity that can be modified using fibre finishes and other treatments _ Provides fabrics with good bulk and cover _ Chemical stability _ Biological degradation resistance (mildew, perspiration) _ Stain and soil release _ Good mechanical strength and abrasion resistance Polypropylene is available in a variety of grades and its surface chemistry, absorbency, mechanical properties, degradation, softness, flame retardancy and colouration are modified by auxiliary chemicals and other treatments by the fibre suppliers. Fibres having different cross-sectional configurations are also available, which affect the physical properties of resulting fabrics. The unique combination of properties offers the manufacturers of nonwovens a valuable high-performance nonwoven fibre for a competitive price. Binders For many years, almost all nonwovens required a chemical binder in order to provide any measure of structural integrity. In addition, the binder was called upon to contribute and convey numerous properties that were necessary for the effective performance of the fabric. In the very early stages of of nonwovens development, different types of natural resins and glues were used to bond nonwovens. Later on, synthetic binders were developed to meet the structural and performance requirements of nonwoven fabrics. Adding a latex binder can be a cost-effective way of consolidating a fiber web and achieving specific properties. It often results that adding a latex binder can be done at a lower cost than using a special binder fiber. In many cases, there can be a combination of chemical binder with mechanical and thermal bonding techniques, affording the finished fabric properties that would be impossible to achieve otherwise. Furthermore binder systems can acceppt pigments and dyes, so they can often help in adding color to nonwoven fabrics. Additives Many non-fibrous materials are used in the manufacture, bonding and finishing of nonwoven webs. Many of these are applied in one form or another to the preformed web ussually after bonding and as a secondary process. Additive materials which are properly classified as raw materials are those added to the fibre or filament structure during web laydown and might include thermally active powders and absorbents. END PRODUCTS USAGE NONWOVEN PRODUCT APPLICATIONS Below are the various examples of nonwoven product applications, though not exhaustive: Hygiene Baby diapers and training pants, Adult incontinence pads, sanitary napkins, tampons, cosmetic removal pads, nasal strips, disposable underwear Wipes Disposable wipes (dry and pre- moistened), Dusters, Dishcloths, Mops Medical and surgical Surgical swabs, Wound dressings, Surgical gowns, masks and caps, Orthopaedic casts, Surgical drapes, wraps andpacks, Transdermal drug delivery, Heat and procedure packs Protective clothing Disposable clean-room garments, Laboratory overalls, Fire protective linings, Thermal insulation fillings, High visibility clothing, Chemical defence suits Filtration (gas and liquids) Teabags, drinks filtration, oil sorption, industrial gas filtration, respiratory filters, vacuum filter bags, odour control. Interlinings and garments Fusible interlinings linings, Shoulder pads, Glove linings Shoes, leather- goods and coating substrates Boot and shoe lining, Synthetic leather shoe uppers, Shoe construction components, Luggage and bags Upholstery,furniture and bedding Ticking, Mattress pads, Waddings & fillings, Sheets and blankets, Window blinds, Quilt backings, Dust covers Floor- coverings Contract carpets and carpet tiles, Underlays and carpet backing fabrics, Automotive carpets and trims Building and roofing House wrap, Thermal and sound insulation, roof linings,under-slating, Plaster board facings, pipe wraps, Fabric tiles (shingles) Civil engineering and geosynthetics Landfill membrane protectors, Drainage systems, Lining systems for reservoirs and ponds, Erosion control and ground stabilization, Soil separation.

Non Woven Interlining Fabric, Buttons, Hair Pins, girls hair accessories

Ultra Non Woven is the reckoned entity engaged in manufacturing and supplying varied collections of Nonwoven fabrics in India.

Non Woven Fusible Interlining

Angel Metallic Jacquard Fabric, bridal laces, organza fabrics

Non Woven Fabrics, Dispensers, hand sanitizers, Liquid Soap

Hydrophilic Non Woven Fabric, Laminated Non Woven Fabric

non-woven fabrics, Synthetic Yarn, Fabrics

Spunlaced Fabrics, Spun Bond Filters

Non Woven Fabric, Surgical Dressings, Medical Disposables, Steam Coal

Non Woven Interlining, Microdot interlining, Cuffs Interlining, suit lining

Non Woven Fabrics, preformed tracheal tube, Surgical Cotton