How Waste PET Fabrics Are Recycled into High-Value Fibers and Pellets

Recycling PET bottles is already a mature industry. Recycling PET fabrics, however, is an entirely different engineering challenge.

Garment factory offcuts, used polyester clothing, home textile waste, and industrial fiber scraps do not behave like rigid plastics. They are soft, entangled, dyed, blended with other fibers, and often contaminated with oils, labels, metals, and finishing chemicals. If the same recycling logic used for bottles is applied to fabrics, the line will quickly clog, the washing will be ineffective, and the final IV of PET will collapse during melting.

This is why PET textile recycling has gradually evolved into a specialized recycling discipline with its own process logic, equipment configuration, and control philosophy.

In modern plants, the mainstream solution is still physical recycling, focused on producing recycled polyester fiber and fiber-grade pellets, while chemical recycling is reserved for high-end applications.

Why Sorting PET Fabrics Is Much More Complex Than Bottle Recycling

The raw materials mainly include:

Garment polyester offcuts

Used polyester garments

Home textile waste

Industrial PET fiber scraps

Unlike bottles, fabrics contain:

Cotton, spandex, nylon blends

Metal zippers and buttons

PP/PE labels and sewing threads

Oil stains, dyes, and finishing agents

Heavy dust contamination

Before entering the line, materials must go through:

Manual pre-sorting for large impurities

Metal removal via eddy current separators

NIR optical sorting for material and color control (purity ≥98%)

Density separation using saltwater flotation based on PET’s density of 1.38 g/cm³

Proper sorting is not just about cleanliness — it directly determines how difficult the washing stage will be and how stable the IV can be maintained later.

The Real Core: Making Fabrics “Washable”

The biggest problem with textiles is entanglement. Long fibers wrap around shafts, resist washing, and trap contaminants inside.

Therefore, the first stages are not about size reduction, but about structure destruction.

Pre-shredding to Prevent Tangling

A low-speed, high-torque single-shaft shredder cuts fabrics into 50–100 mm strips. This prevents wrapping and ensures stable feeding.

Crushing and Fiber Opening — The Step That Defines Success

After coarse crushing into 10–30 mm pieces, a fiber opener (carding machine) turns compact fragments into fluffy, separated fibers.

This step is unique to textile recycling.

Often, an alkaline pre-treatment (5–10% NaOH at 45–55°C) is applied here to:

Remove dyes and finishing oils

Break fiber cohesion

Prepare materials for deep washing

At this point, the material finally becomes washable.

Multi-Stage Washing: Where Final Quality Is Determined

Once fibers are opened, effective washing becomes possible.

Ambient friction washing removes dust

Hot washing at 80–95°C with NaOH and surfactants removes oils, dyes, and chemicals

Friction washers provide mechanical scrubbing

2–3 stage counter-current rinsing ensures neutral pH

The wastewater at this stage contains high COD, SS, and dye content, requiring coagulation, air flotation, biological treatment, and decolorization. Modern systems allow 80–95% water reuse.

Moisture Control: The Key to Preventing IV Degradation

After washing:

Centrifugal or screw dewatering reduces moisture to ≤8%

Hot air or fluidized bed drying at 120–160°C reduces moisture to ≤0.5%

This is critical. Excess moisture during melting is the primary reason PET molecular chains break and IV drops.

From Clean Fibers to Pellets or Recycled Polyester Fiber

Melt Granulation

Using a high-torque twin-screw extruder:

250–280°C melting

Vacuum devolatilization<0.3 kPa

Underwater pelletizing

IV drop can be controlled within 5%.

Fiberization — The Main Value Output

Most PET fabric recycling lines aim at fiber production:

Melt → Spinning → Drawing → Crimping → Cutting

Applications include yarn spinning, non-wovens, filling materials, geotextiles, and automotive interiors.

When Physical Recycling Is Not Enough: Chemical Depolymerization

For mixed colors or heavily contaminated textiles, alkaline hydrolysis or alcoholysis breaks PET into PTA and EG, followed by purification and repolymerization into food-grade PET with 99.9% purity.

This route is costly but suitable for high-value markets.

Key Equipment in a PET Fabric Recycling Line

Shredder

Metal separator

Crusher

Fiber opener

Friction washer

Rinsing tanks

Dewaterer

Dryer

Twin-screw extruder + underwater pelletizer

Wastewater treatment system

Product Quality and Applications

Recycled pellets: fiber grade, injection grade, blow molding grade

Recycled fibers: apparel, home textiles, non-wovens, automotive

Quality targets:

IV ≥ 0.6 dl/g

Moisture ≤ 0.5%

Ash ≤ 0.1%

Impurities ≤ 50 ppm

Costs and Environmental Performance

Physical recycling: 800–1,500 RMB/ton

Chemical recycling: 3,000–5,000 RMB/ton

Pellet value: 3,000–5,000 RMB/ton

Water reuse up to 95%, with exhaust and sludge properly treated.

Conclusion

PET textile recycling is not a simplified version of bottle recycling. It is a fiber-oriented recycling technology built around:

Preventing entanglement

Opening fibers before washing

High-temperature impurity removal

Strict moisture control to protect IV

Effective wastewater reuse

When these principles are correctly applied, waste polyester textiles can be transformed into high-quality recycled fibers and pellets, completing the circular lifecycle of polyester materials.