main technologies.
-spunbond
- spunlace
- needle punch
- meltblown
- stichbond
excellence in
- multi-layer lamination
with polyurethane films
with acrylic adhesive
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- converting
rewind cutting
non-woven moldings
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refinements.
- multi-layer
- embossing
- printing
- powder
-imprignation
-coating
-lamination
-converting
needle punch.
The fibers are needled together using a needle beam (theoretically, one can also refer to it as felting). Due to the chaotic arrangement of the fibers, needle punch nonwoven fabrics have very high strength and are dimensionally stable.
surface.
The surface is rather uneven, and there may be larger fluctuations in grammage at certain points. Due to needling, the nonwoven fabrics are very soft.
structure.
Needle punch nonwoven fabrics have an irregular fiber structure, which provides exceptionally strong stability in all directions. For mechanically demanding applications, needle punch nonwovens are always preferred.
stichbond.
The reinforcement of nonwoven fabrics through additional threads, which can protect the fabric from deformations, for example, is commonly referred to as "stitchbonding" or "stitching reinforcement." This process involves the incorporation of threads or yarns into the nonwoven fabric structure during manufacturing to enhance its strength, stability, and resistance to deformation.
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surface.
A very even and strong surface.
structure.
The fabrics struture is protected by the stichbonding.
spunbond.
In the production of spunbonds, fine fibers are extruded onto each other, and subsequently thermally bonded through a roller. This process creates very tear-resistant and stable nonwoven fabrics.
surface.
Spunbond fabrics are known for their excellent strength and durability. The continuous filament fibers used in spunbond production provide a strong and robust fabric structure that can withstand mechanical stress and tearing.
structure.
Spunbond fabrics have a consistent and uniform structure, which ensures predictable performance and quality. This uniformity makes them suitable for applications where consistency is critical
meltblown.
Due to their fine fibers, meltblown nonwoven fabrics offer excellent filtration efficiency for airborne particles and liquids. They are commonly used in respiratory masks, face masks, air filtration systems, and liquid filtration applications.
Meltblown nonwoven fabrics have a high liquid absorption capacity. They can absorb large amounts of liquid, making them ideal for use in hygiene products such as diapers, sanitary pads, and medical dressings.
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Resistance to Chemicals and Moisture: Meltblown nonwoven fabrics can exhibit good resistance to chemicals and moisture, enhancing their durability and performance in different environments.
surface.
Despite their fine fibers, meltblown nonwoven fabrics are soft and provide comfortable wear. This makes them suitable for products that come into direct contact with the skin, such as hygiene products and medical dressings.
structure.
Meltblown nonwoven fabrics are composed of extremely fine fibers typically in the micron range. These fine fibers provide a high surface-to-volume ratio, leading to improved filtration performance.
spunlace.
The structure of spunlace nonwoven fabrics is determined by the manufacturing process known as spunlacing. In the spunlacing process, loose fibers are entangled and bonded together using high-pressure water jets to form a nonwoven fabric. The structure of spunlace nonwoven fabrics may vary based on specific application requirements.
surface.
The spunlacing process creates a even and soft surface that is pleasant to the touch. This characteristic makes spunlace nonwoven fabrics particularly suitable for applications where skin contact is important, such as in the hygiene industry.
structure.
Spunlace fabrics have an open, porous structure that allows for excellent air and liquid permeability. The even distribution of fibers results in a very soft and flexible. Certain properties can be adjusted through additives or chemical finishing.
spunbond.
+ chemical treathments.
Chemical finishing of nonwoven fabrics enables the achievement of specific properties and functions that meet the requirements of various applications, enhancing the performance and versatility of the material.
surface.
Chemical finishing processes can also be used to make nonwoven fabrics hydrophobic, meaning they are water-repellent. Chemical treatments can impart nonwoven fabrics with antibacterial or antimicrobial
structure.
Chemical finishing processes can increase the strength of nonwoven fabrics. This can improve the tear resistance, abrasion resistance, and tensile strength of the material.
Refinements
embossed spunlace.
Overall, embossing nonwoven fabrics can enhance their aesthetic, functional, and structural properties, increasing their versatility in a variety of applications
surface.
Embossing nonwoven fabrics can create aesthetic and decorative effects. By embossing, interesting patterns, textures, or logos can be incorporated into the fabric to enhance its appearance and generate visual interest.
structure.
Embossing can reinforce nonwoven fabrics and improve their structural stability. This is particularly useful in applications where the fabrics are subjected to high mechanical stress, such as in technical applications in construction or the automotive industrie.
spunlace printed.
We can print your spunlace with your logo or in any need for your application.
surface.
Printed surfaces can help you to advertise your product or bring a special function on the product.
structure.
We can print in digital or transfer print on your nonwovens.
multi-layer.
needle punched.
We can produce multi-layer so we can add films or also different type of nonwoven layers to archive different kind of properties e.g. membranes with a breathable function layer
surface.
The outer layers can be ether nonwovens,films or hotmelt powders
structure.
As the outside layer can be a varios types of layers, you can use a big list of functional structures for your applications.
punched spunlace.
Packaging:
Perforated nonwoven fabrics are also utilized in the packaging industry to facilitate ventilation and moisture exchange in packaging for food, flowers, or other delicate goods.
surface.
Very stable mechanical structure.
structure.
High breathable structure.
development.
For any special demand please contact our technical sales team.