Melt blowing technology precisely forms nonwoven fabrics possessing extremely fine fiber diameters and a variety of productive applications. Sophisticated machinery lies at the heart of this specialized manufacturing process.

How it Works

Thermoplastic resin pellets are melted and extruded through microscopic die openings, forming continuous streams of molten material. High-velocity hot air flows split and attenuate the filaments as they exit, drawing them into micro-thin fibers between 0.1-10 microns in diameter. The airstreams convey fibers onto a moving belt where they collide, entangle and form a unified web. Deposited fibers cool and solidify, resulting in a uniform nonwoven sheet.

Machine Design

Precise die engineering determines fiber size and web properties. Small variances impact filtration efficiency or texture. Dies heat plastics evenly to controlled melt temperatures without decomposition. Multi-orifice designs maximize throughput. Air knife assemblies precisely regulate pressures and velocities stabilizing filaments. Specially coated collectors uniformly consolidate webs. Industrial-grade frames, bearings and motors withstand intensive operation. Programmable logic controls optimize running parameters.

Processing Flexibility

Adjustable process variables tailor webs for end uses. Altering air velocity/temperature and resin type influences fiber morphology, basis weight, pore structure and mechanical properties. Bi-component configurations core a lower-melting skin around a higher-melting core for specific effects. Continuous rolling production accepts an array of feedstock types suited to varied filtration or absorption applications.

Quality is Paramount

Precise fiber microstructure dictates performance, so quality control remains critical. Online monitoring detects deviations in line speed, air pressures, fiber diameter or web uniformity for swift adjustments. Post-line testing evaluates properties like pore size, static charge, strength and permeability. Strict changeover procedures minimize contamination when switching resin types or winding bulk continuous rolls in clean room environments.

Engineering Excellence

Leading machinery OEMs conduct extensive R&D optimizing designs, crucially in areas like die tips featuring advanced surface modifications extending service life under corrosive processing conditions and minimizing waste. They establish global reputations through process expertise delivering consistent, validated products fulfilling the most stringent industrial standards. Thoughtful automation and ergonomic designs maximize uptime safely meeting bulk production demands cost-effectively.

In Conclusion

Specialized melt blown fabric machine lies at the core of manufacturing superior nonwoven fabrics supporting industries from healthcare and HVAC to geosynthetics and beyond. Continued engineering progress ensures this technology sustainably produces filtration media and materials helping global populations for decades to come.

From medical masks to air and liquid filtration media, melt blown nonwoven fabrics play a crucial role in modern industries and our daily lives. These specialized fabrics are produced through an advanced process utilizing melt blown fabric machines. Let’s explore the inner workings of this sophisticated technology.

How It Works

In a melt blowing machine, polymer pellets (usually polypropylene or polyester) are continuously fed into an extruder barrel and heated to melt. The extrudate emerges through fine diameter spinneret die openings which divide it into filaments. High-speed heated air blows these filaments through attenuated air flows, stretching and thinning them as they are deposited in a collected web on a conveyor belt.

Key Components

Extruder melts and pumps polymer through the die head assembly. Temperature must remain precisely controlled.

Spinneret die plates contain thousands of micro-sized openings to divide the stream into fine filaments. Plate designs vary hole sizes and patterns.

Heated air guns directed at the filaments use air pressures from 100-500 PSI and temperatures from 200-400°F to draw out filaments.

Collection belt gathers deposited filaments into a nonwoven web which proceeds through heating/cooling rolls.

Fabric Properties

Filament diameters ranging from 0.5-10 microns yield high surface area webs from a few GSM up to several hundred. Fiber entanglement provides good strength while porosity and pore size distribution impart desired properties for filtration or PPE use. Machines precisely modulate fiber deposition parameters and web handling for consistent quality.

Filtration Applications

Common melt blown fabrics serve in masks, respirators, industrial and HVAC air filters, vacuum cleaner and engine air filters, oil filters and more. Through efficient depth loading and small pore structures, they effectively capture particles or liquids via various mechanisms down to sub-micron levels.

Quality Factors

Manufacturers evaluate web uniformity, thickness variation, particle/liquid filtration efficiencies and mechanical properties to ensure product suitability. Proper spinneret design, temperature controls, air velocity profiles and collection all influence outcomes requiring sophistication. Regular audits maintain optimized performance.

Overall, melt blowing utilizes precisely engineered thermoplastic processing and fiber formation methods delivering specialized nonwoven fabrics with diverse application ranges through consistent fine fiber production. Their crucial filtration roles rely on high-quality machine output.

Nonwoven fabrics make up a large portion of disposable consumer goods like hygiene products, wipes, medical products and more. One of the most common techniques for manufacturing these versatile materials is the spunbond process, which forms continuous filaments into a random web structure. This blog post will explore how spun bond non woven fabric machines work and the factors engineers consider in their design.

The Spunbond Process

Spunbond starts with polymers like polypropylene, polyethylene or polyester resin pellets being melted and extruded through fine spinnerets containing hundreds to thousands of holes, each creating a continuous filament. The filaments are then stretched or drawn using high-speed rollers to align the polymer molecules and strengthen fibers. Next, the filaments are deposited randomly through air onto a perforated collector belt where they form a nonwoven web.

Key Machine Components

Spinneret: Plates with thousands of tiny holes precisely designed and spaced to control fiber diameter.

Extruder: Melts and pumps polymer through spinnerets at high temperatures and pressures.

Quench Tower: Bombards filaments with heated air or liquid to cool rapidly after extrusion.

Draw Rollers: Sets of gapped metal drums spin at different RPMs to stretch, draw and align molecular structure of fibers.

Deposition Head: Guide filaments through air onto collecting belt below to entangle fibers randomly.

Belt: Moves web continually forward or in S-wrap patterns under deposition head.

Calender Rollers: Compress web thickness and smoothing using heated steel rolls.

Winding System: Collects continuous web onto parent rolls for storage or further processing.

Key Design Considerations

Producing nonwoven webs at high speeds requires precise synchronization of components. Spunbond machines are engineered for:

• Throughput: Rates exceeding 500 meters/minute producing 10,000+ tons annually.
• Fiber Attributes: Diameter, crimp levels and tensile properties adjusted through die and process conditions.
• Web Uniformity: Even dispersion and entanglement of fibers for consistent material properties.
• Mass Per Unit Area: Range from 10-100+ gsm requiring adjustments to machine settings.
• Material Compatibility: Chemically inert and temperature resistant materials used.
• Automation: Process monitoring, controls and reporting facilitate consistent quality output.
• Safety: Guards, interlocks and platforms allow accessible yet cautious maintenance.

Well-designed spunbond lines utilize advanced engineering to deliver predictable, quality nonwoven production at scale.

Quality Considerations

Key quality metrics for spunbonded fabrics include:

• Basis Weight Distribution: Even mass distribution across web width and between production lots.
• Fiber Distribution & Entanglement: Proper levels and randomness ensured through controlled deposition.
• Web Thickness: Calender rolls compress fibers uniformly without defects.
• Tensile Strength: Depends on polymer, draw ratio and processing used.
• Liquid Barrier Properties: Important for absorbents, wipes and sterilization wraps.
• Microbial Feeds: Tested for pathogen elimination in medical-grade materials.
• Package Quality: No defects after parent roll slitting, sheeting or punching.
• Quality control systems precisely monitor these attributes during production runs.

Spunbond non-woven fabric is a relatively popular fabric now. Spunbond non-woven fabric has many advantages. Therefore, it has been widely welcomed at all ages. So, how to manufacture large-scale spunbond non-woven fabrics? Naturally, it is necessary to rely on an automated equipment called spunbond non-woven fabric equipment to achieve mass production. The performance requirements of spunbond non-woven equipment are also relatively high. Our manufacturer has done a lot of improvement and research and development work, so that spunbond non-woven equipment has the following excellent equipment characteristics. Let’s take a look.

Equipment characteristics of spunbond non-woven machinery

1. The spunbond non-woven equipment is built with excellent assembly and welding technology as a whole. It has a strong structure, high strength, durable performance, stable operation, and can maintain a good working condition for a long time in a high-load processing environment.
2. The automatic operation design is simple and convenient, and there is no burden for the operator. The use of spunbond non-woven machinery can save a lot of labor costs and achieve higher benefits for enterprises.
3. With stable and reliable processing quality, the overall non-woven products show uniformity, which can maintain a high degree of quality uniformity, reduce the defective rate, greatly improve the market competitiveness of anti-stick non-woven products, and bring continuous continuous improvement to the enterprise. income.
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   As a popular high-quality fabric, spunbond non-woven fabrics naturally need to pay attention to the quality of the process during the production process. Choosing a high-quality processing equipment can significantly improve the quality of spunbond non-woven fabrics. For this, very good quality control can be achieved with our spunbond nonwoven machines.

Have you ever worn a disposable diaper, used a filter, or gone shopping with reusable shopping bags? If so, you’ve likely interacted with spun bond nonwoven fabrics without even knowing it. Spun bond nonwovens are versatile materials widely used in a variety of applications ranging from hygiene and personal care products to industrial filtration and construction materials. In this blog post, we’ll take a deeper look at what spun bond nonwoven fabrics are, how they’re produced, their properties, and common uses.

Spun bond non woven fabrics are manufactured through a process known as spun bonding. In this process, continuous polymer filaments are as extruded through a spinneret and drawn out onto a conveyor belt. As the filaments extruded, they cooled and drawn out simultaneously by winders, quenching towers, and rollers. This draws and orientates the filaments into long strands. The filaments are then as deposited in a randomly distributed overlapping web-like structure on the conveyor belt through mechanical drawing. They are then as bonded together, either through hot air, chemical bonding, or ultrasonic bonding to form a coherent nonwoven fabric.

The key advantage of spun bond nonwovens over other nonwoven processes

Itlike meltblowing or needle punching is that the continuous filaments retain their individual identity even after bonding. This results in nonwovens that are stronger, with higher tensile strength and tear resistance compared to other nonwoven processes. Spun bond fabrics also have very low densities, are uniform in structure and thickness, and are highly permeable to gases and liquids. Some key properties of spun bond nonwovens include:

• High strength and tear resistance
• Uniformity of structure/thickness
• Low density
• Good abrasion resistance
• Permeability to gases and liquids
• Soft hand or feel similar to woven fabrics
• Can be as produced in wide widths on continuous production lines

A wide variety of polymers can be as used to produce spun bond nonwovens including polypropylene (PP), polyester (PET), polyethylene (PE), nylon, and biodegradable polymers like polylactic acid (PLA). However, polypropylene is by far the most commonly used polymer due to its good mechanical properties, chemical resistance, low cost and recyclability. The properties of the resulting spun bond fabric can be as varied by adjusting processing parameters like spinneret design, throughput rate, filament diameter, bonding methods and bond pattern.

Some of the most common applications of spun bond nonwovens include:

• Hygiene Products – Spun bond PP nonwovens extensively used as topsheets and backsheets in disposable diapers, adult incontinence products, and feminine hygiene products due to their breathability, absorbency and fluid handling properties.
• Spun bond PP nonwovens extensively used as topsheets and backsheets in disposable diapers, adult incontinence products, and feminine hygiene products due to their breathability, absorbency and fluid handling properties. Wipes – Wet wipes often contain a spun bond backing to provide strength and integrity to the wipe.
• Wet wipes often contain a spun bond backing to provide strength and integrity to the wipe. Filtration – Spun bond nonwovens used to make a variety of filter media for applications like air filters, liquid filters, face masks etc. due to their high permeability and particle retention abilities.
• Spun bond nonwovens are as used to make a variety of filter media for applications like air filters, liquid filters, face masks etc. due to their high permeability and particle retention abilities. Geotextiles – In construction, spun bond polypropylene nonwovens used as separators, reinforcements and drainage meshes in applications like roads, foundations and retaining walls.
• In construction, spun bond polypropylene nonwovens are as used as separators, reinforcements and drainage meshes in applications like roads, foundations and retaining walls. Apparels – Spunmelt nonwovens are becoming increasingly popular in clothing like sports apparel and athletic gear for their moisture wicking and quick drying properties.
• Spunmelt nonwovens are becoming increasingly popular in clothing like sports apparel and athletic gear for their moisture wicking and quick drying properties. Agriculture – They used as weed barriers, mulch fabrics and silage wraps in agriculture applications.

They are as used as weed barriers, mulch fabrics and silage wraps in agriculture applications. Packaging – Carry bags, wrappers, envelopes commonly made from spun bond nonwovens. Their high strength and moisture resistance makes them suitable for these applications.

A diverse range of industries

As you can see, the versatility of spun bond nonwovens has led to their widespread use across a diverse range of industries. Their unique combination of mechanical strength, uniformity, permeability and low cost manufacturing gives them distinct advantages over other nonwoven and woven materials. With continuous technological improvements, new spun bond processes and usage of specialty polymers, we can expect even more innovative applications to emerge for these nonwoven fabrics in the future. They are certainly playing an important role in our daily lives through their use in countless hygiene, medical, industrial and packaging products.

Nonwoven fabrics are engineered fabrics made from synthetic fibers bonded together by chemical, mechanical, heat or solvent treatment. They are mainly used for filtration, hygiene products, medical applications, geotextiles and more. Meltblown nonwovens are a type of nonwoven fabric made by extruding thermoplastic fibers that are blown by high-velocity air onto a conveyor belt. The fibers bond and entangle as they land to form a fine, breathable fabric. Meltblowing is one of the most effective technologies for creating top-quality filters. This blog post will provide an overview of meltblown machine nonwoven fabric and its manufacturing process and applications.

How Meltblown Nonwovens Are Made?

Meltblown nonwovens are made through a specialized extrusion process called meltblowing. Polymer resins, usually polypropylene or polyethylene, are first melted and then extruded through tiny nozzles surrounded by high velocity hot air. As the hot air blows onto the molten polymers coming out of the nozzles, it stretches them into micro and nanofibers, allowing the fibers to get extremely thin in diameter, typically ranging from 1 to 10 microns. The fibers are then laid randomly onto a moving belt to form a nonwoven web. The entanglement of the ultrafine fibers as they land and bond to each other results in a very dense barrier fabric.

The meltblowing process allows control over final fabric properties such as fiber diameter, basis weight, and pore size based on factors like the polymer viscosity, air flow rate, distance between the nozzle and the collecting belt, as well as belt speed. This high level of control allows the creation of tailored nonwovens for specific applications. Meltblown fabrics are known for their barrier properties, fine fiber filtration efficiency, absorption characteristics and high surface area.

Key Components Of A Meltblown Machine

The main components of a meltblown machine include:

• Extruder: Melts the polymer resin and pumps it at a constant rate to the meltblowing die.
• Meltblowing die: Having rows of tiny holes called nozzles or capillaries that the molten polymer extrudes through. High velocity hot air blows onto the polymer streams exiting the nozzles and attenuates them into microfibers.
• Web forming chamber: Where the fiber streams are blown by the high velocity air onto a perforated rotating drum or conveyor belt moving in front of the die. The fibers accumulate on the belt into a meltblown web.
• Bonding method: Can be thermal point bonding with heated calender rolls or hydroentanglement jets that need pressure for fibers to entangle. Provides fabric strength.
• Winding system: Winds the consolidated meltblown fabric into rolls.

Advantages Of Meltblown Nonwovens

Some key advantages of meltblown nonwovens include:

• Very fine fiber diameters, down to submicron sizes. This gives a large surface area.
• High level of filtration efficiency. The microfibers intercept tiny particles and prevent them from passing through the fabric. Meltblowns can remove particles down to 2-3 microns and some even smaller.
• Breathable barrier properties, allowing gas and water vapors to permeate while providing a barrier for liquids. Useful for surgical gowns.
• Good absorbency due to the small interfiber spaces that can hold liquid. Often used as oil absorbents.
• Lightweight fabric with a soft draping handfeel. Does not irritate skin.
• Versatile, cost-effective and can be tailored to many different applications.
• Continuous production method makes high volumes possible.

Applications Of Meltblown Nonwovens

Some of the main uses of meltblown nonwovens are:

• Surgical face masks – Protect against infectious particles thanks to the excellent filtration ability of meltblowns. Most masks have a meltblown middle layer sandwiched between spunbond or other nonwovens providing strength.
• Air filters – Remove airborne particles from air streams in applications like vacuum cleaners, air conditioners and automotives. The submicron diameter fibers catch fine particles.
• Industrial workwear – Apparel like coveralls, gowns and sleeves used where hazardous particle protection is needed.
• Oil absorbents – Can soak up oils and hydrocarbon liquids from spills on land or water. The fabric’s oleophilic but hydrophobic nature is ideal for oil clean-up.
• Battery separators – Prevent direct contact between the anode and cathode in batteries while allowing ion transfer. The microporous structure provides electrical insulation.
• Wipes – For medical, industrial, cosmetic and other wipes where low-linting and softness are desired.
• Hygiene products – Used in diapers to provide a breathable, leakage barrier. Also in feminine hygiene items.

Nonwoven fabrics have become indispensable materials in a wide range of industries from hygiene and medical to construction and agriculture. One of the most versatile and commonly used nonwoven fabrics is spunbond polypropylene, known as PP spunbond. This material offers beneficial properties that make it a top choice for many applications. In this blog post, we’ll explore what exactly PP spunbond fabric is, how it’s produced, its performance properties, and the many uses for this nonwoven textile.

What Is Spunbond Polypropylene Fabric?

Spunbond polypropylene, or PP spunbond, is a nonwoven fabric made from polypropylene filaments. To produce it, polypropylene plastic pellets are first melted and extruded through tiny nozzles to form continuous filaments. As the filaments are extruded, they are rapidly stretched and elongated using high-velocity air jets. The filaments are then deposited on a moving belt in a random pattern to form a web. The web is thermally bonded using heat and pressure to fuse the overlapping filaments. This creates a strong, breathable fabric without any knitting or weaving.

The spunbond process results in a fabric with excellent strength, flexibility, and stability. Polypropylene itself is known for its durability, hydrophobicity, chemical resistance, and affordability. These attributes make PP spunbond a versatile material for many different applications.

Key Properties And Performance

PP spunbond nonwoven fabric offers a unique balance of properties:

• High tensile strength and tear resistance
• Breathable yet dense structure
• Excellent liquid barrier abilities
• Soft, flexible handfeel
• Good dimensional stability
• Resistance to humidity, mildew, and many chemicals
• Stays intact when stretched or strained
• Can be sterilized for medical uses
• Cost-effective and efficient to produce

The combination of strength, flexibility, and barrier properties makes PP spunbond suitable for a wide range of uses from hygiene products to industrial filtration. It can be engineered during production to have different weights, thicknesses, and performance characteristics.

Common Applications And Uses

Thanks to its favorable properties, polypropylene spunbond finds many applications:

• Disposable hygiene products – The fabric is used in diapers, sanitary pads, adult incontinence products, and hospital underpads. It keeps moisture away from the skin while allowing breathability.
• Medical fabrics – PP spunbond is used for surgical drapes, gowns, sterile packaging, and masking fabrics. It provides a bacteria barrier while remaining breathable.
• Geotextiles – When used for geotextile fabrics, PP spunbond provides excellent filtration, separation, drainage, and stabilization for roads, dams, canals, and other structures.
• Crop coverings – Spunbond polypropylene makes ideal crop coverings to protect plants from frost, wind, hail, birds, and insects due to its strength, opacity, and drainage.
• Furniture and bedding – Within furniture upholstery and mattress covers, PP spunbond offers a soft, breathable surface that holds up well to continuous use.
• Industrial workwear – The fabric is often used for protective clothing, aprons, and gloves due to its durable, hydrophobic, and breathable nature.
• Air and liquid filtration – PP spunbond’s dense structure filters out particles, droplets, and aerosols while allowing gases and liquids to pass through.

Conclusion Of Polypropylene Spunbond Nonwoven Fabric

With its unique production process and balance of properties, polypropylene spunbond nonwoven fabric serves a wide array of industries. It delivers strength, breathability, liquid repellency, and bacterial resistance with efficiency and cost-effectiveness. As nonwovens continue to gain market share across textile and technical applications, expect versatile PP spunbond to maintain its prominence for years to come.

A spunmelt nonwoven machine as used to produce various nonwoven materials including hygiene products, filtration media, and apparel fabrics. A common type of spunmelt machine is the polypropylene (PP) single-step sandwich meltblown spunmelt machine (SSMMS), which produces combined spunbond and meltblown webs in a single process. This PP SSMMS spunmelt machine offer high performance and yield for nonwoven manufacturers.

Introduce about PP SSMMS spunmelt machine

In a PP SSMMS spunmelt machine, polymer granules like polypropylene are first fed into a hopper and conveyed into the extruder. Inside the extruder, the polymers are melted and forced through a spinneret. The spinneret contains many tiny holes that create continuous polymer filaments as they exit.

As the molten filaments exit the spinneret, they are drawn vertically by a godet system where they are cooled by air. As the filaments harden, they become thinner and more stable, forming continuous fibers. These fibers then pass through the sandwiching area where hot air to form the meltblown layer is injected in between the spunbond layers.

The sandwiching area is a key feature of single-step SSMMS machines. In this section, the spunbond fibers pass between an upper and lower conveyor, with hot air blown from nozzles in between to create the meltblown layer. The amount of hot air, air pressure and nozzle arrangement determine the basis weight and thickness of the meltblown layer.

After sandwiching, the combined web consisting of spunbond and meltblown layers passes over a roller bed and into an oven for annealing and further cooling. The annealed composite web is then wound onto a take-up roller.

The key advantages of PP SSMMS machines include:

• High production rates – Up to 800 kg/hr of nonwoven material can be produced.
• Width flexibility – Web widths from 1.2 to 4.5 meters are possible, depending on the machine.
• Better control of layer ratios – The combination ratio of spunbond to meltblown layers
  can be precisely set from 20/80 to 80/20.
• Uniform web weights – Precise control of spinning, air flow and winding ensure consistent
  basis weights within +/- 3%.
• Superior quality and performance – The integrated process produces composite webs with
  bonding between layers for improved strength, barrier properties and filtration.

PP SSMMS machines also require less space and capital investment compared to traditional two-step systems that produce spunbond and meltblown layers separately and laminate them later. However, the single-step process does involve more complex control of the sandwiching section.

When selecting a PP SSMMS spunmelt machine, manufacturers should consider factors like web width, production rate, layer ratio flexibility, Energy efficiency, technical support and maintenance requirements. Machine suppliers often offer custom configurations and options to meet the specific application needs for products like diapers, wipes, filters and geotextiles.

Nonwoven fabrics are essential materials used in everything from diapers and medical fabrics to geotextiles and automotive applications. As demand rises, manufacturers are seeking out the latest technology in spunbond nonwoven fabric make machine to improve productivity and product performance.

What Is Spunbond Fabric And How Is it Made?

Spunbond or spunbonded fabrics are a popular type of nonwoven made from extruded, spun filaments bonded together to form strong, durable webs. The spunbond process starts with polymer resin pellets fed into an extruder where they are melted at high temperatures into a polymer solution.

The molten polymer is pumped into a spinneret block featuring hundreds of tiny nozzles that spin the polymer into fine continuous filaments as they are extruded. Cooling air blows onto the filaments as they are spun to solidify them.

The filaments are drawn onto a conveyor belt where they are deposited in random orientations to form a web. This web then passes through heated calender rollers that bond the intersecting fibers together through a combination of mechanical entanglement and thermal fusion.

The final spunbond fabric is wound into rolls to be further finished or converted into end products. Variations in polymers, production parameters, and bonding methods yield spunbond materials with unique properties for different applications.

Benefits Of Advanced Spunbond Nonwoven Machines

Spunbond nonwoven manufacturing has come a long way from early belt-based processes developed in the 1970s. Today’s state-of-the-art spunbond lines offer major advantages like:

• Higher speeds and throughput – Modern spunbond lines can run at speeds exceeding 1000m/min to maximize production.
• Superior web uniformity – Advanced metering pumps, spinnerets, and other features improve weight and thickness consistency.
• Finer filaments – Filaments down to 1 micron in diameter produce smoother, finer fabrics.
• Composite fabrics – Some systems can produce SMS, SSMMS, and other composite structures.
• Better energy efficiency – Optimized process controls reduce power consumption.
• Reduced downtime – Equipment designed for quick changeovers, maintenance, and expanded production windows.
• Improved end product quality – Tighter process control, versatile polymer options, and better web bonding lead to higher performing fabrics.
• Smart monitoring – IoT integration and data analytics help identify process optimization opportunities.

These capabilities allow manufacturers to gain a competitive edge with their spunbond nonwovens.

Key Spunbond Line Components And Technologies

Some noteworthy components and technologies available on state-of-the-art spunbond lines include:

• High-speed, high-output extruders – Gala underwater pelletizers offer precision polymer melting and delivery.
• Advanced metering pumps – Accurate polymer filtering, pressure regulation, and flow control.
• High hole density spinnerets – Up to 8000 holes produce more filaments and finer webs.
• Optimized quenching – Strategically placed cooling systems solidify and draw filaments consistently.
• Web handling systems – Vacuum devices and electrostatic pinning smoothly convey the spunbond web.
• Multibeam thermal bonders – Computer-controlled bonding achieves precise caliper, tensile strength, and softness.
• Surface treatment – Corona, plasma, or flame treatment allows better printing, lamination, and liquid absorption.
• Quality control systems – Auto gauging, sampling, and defect detection ensure consistent output.
• Remote monitoring and control – IoT systems enable data-driven optimization and predictive maintenance.
• With such features, manufacturers can create high-performing spunbond materials to meet any specifications.

Partner With A Leading Spunbond Line Manufacturer

As a premier maker of turnkey spunbond, meltblown, and composites lines for over 20 years, XYZ Machinery is an ideal partner for your next spunbond project. Our extensive expertise in engineering tailored spunbond solutions includes:

• 3D modeling of custom configurations
• Precision manufacturing of equipment
• Turnkey line installation and optimization
• Local after-sales service and support
• Operator training and maintenance

Whether you need a complete greenfield installation, upgraded line components, or a debottlenecking of your existing process, XYZ Machinery has the capabilities and experience to deliver maximum performance and value.

Meltblown nonwoven fabric machines use high-speed hot air to produce light, porous fabrics made of extremely fine fibers. These machines have many applications in industries like healthcare, filtration and apparel.

What Is A Meltblown Nonwoven Machine?

A meltblown nonwoven machine is a special type of extrusion equipment used to manufacture meltblown machine nonwoven fabric. It works by extruding thermoplastic resins through fine nozzles and blowing heated air at high velocities onto the extruded filaments.

As the filaments exit the nozzles, the hot air attenuates and entangles them, forming a web of fine fibers that is collected on a conveyor. The resulting nonwoven fabric is lightweight with very small fiber diameters.

Meltblown machines typically have three main components:

• Extruder – Melts the thermoplastic resin pellets or granules and extrudes it through nozzles.
• Distribution plate with nozzles – The melt is forced through thousands of tiny nozzles to form the filaments.
• Hot air system – High-velocity air heats up as it passes over a chamber and is then blown onto the extruded filaments.

The hot air stretches and attensuates the filaments as they exit the nozzles, forming fine fibers that quickly mix and entangle on a rotating forming surface. The nonwoven web is then conveyed to a winding unit.

Key Parameters of Meltblown Machines

• Nozzle holes – The number and diameter of nozzle holes determine the fineness of the fibers and fabric basis weight.
• Air temperature – Higher air temperatures produce finer fibers but can damage the resin.
• Airflow – Higher air velocity produces finer fibers but consumes more energy.
• Resin type – Different resins like PP, PE and PET are used based on fabric properties required.
• Production speed – Higher speeds allow more fabric production but affect fiber fineness.
• Width – Machine width determines the size of the nonwoven fabric produced.

Machine manufacturers optimize these parameters to produce meltblown fabrics with the properties required for specific end uses. Wider machines with more nozzle holes can produce higher output.

Applications of Meltblown Nonwoven Fabrics

Attributes of meltblown nonwoven fabrics that enable various applications:

• The fine fiber diameter produces high porosity and surface area.
• They are light due to weighing between 10 to 300 gsm.
• The fabrics exhibit good barrier properties against microbes, liquids and particles.

Common uses of meltblown nonwoven fabrics:

• Healthcare: They are used in surgical drapes, gowns, masks and swabs.
• Filtration: They serve as filter media for air, liquids and other applications.
• Apparel: They are used as interlinings and insulation layers in clothing.
• Wipes: They are used to make wet wipes for personal and industrial cleaning.
• Acoustics: They are used as sound insulation in buildings and vehicles.