HDPE 및 LDPE가 재활용 기계 설계 및 사양에 미치는 영향

When designing recycling machinery, understanding the distinct characteristics of High-Density Polyethylene (HDPE) and Low-Density Polyethylene (LDPE) is critical.

These two plastics differ significantly in properties, affecting machinery selection, operational parameters, and overall recycling costs. This guide offers comprehensive insights into how these differences influence machinery specifications, helping readers make informed decisions for effective recycling operations.

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A. Sorting and Separation: Tailoring Technologies to Resin Characteristics

Efficient sorting is fundamental to producing high-quality recycled materials. The choice of sorting technology depends greatly on whether you’re processing rigid HDPE containers or flexible LDPE films.

HDPE Sorting Techniques

HDPE typically has a density of 0.941–0.970 g/cm³, allowing it to float in water. This property simplifies separation from denser plastics like PET and PVC using float-sink tanks. Additionally, Near-Infrared (NIR) optical sorters are effective for distinguishing between natural and colored HDPE and separating HDPE from other polymers. However, dark pigments (L-values ≤40 or NIR reflectance ≤10%) can reduce NIR sorting accuracy. The rigid form of HDPE products, such as bottles, aligns well with conventional sorting conveyors, screens, and optical systems, although small items may be mistakenly removed with glass fines in some facilities.

LDPE Sorting Techniques

LDPE has a lower density of about 0.910–0.940 g/cm³, also enabling floatation-based separation. Yet, distinguishing LDPE from HDPE in mixed streams poses a challenge. The flexible, film-based nature of LDPE frequently leads to tangling and blockages in automated systems, significantly reducing sorting efficiency. Therefore, specialized equipment like ballistic separators, air classifiers, or extensive manual sorting is required. Initial sorting of LDPE is typically based on its two-dimensional film shape versus three-dimensional containers.

Cost Implications of Sorting

Sorting machinery for LDPE film is typically more complex and costly due to specialized features preventing tangling and the higher reliance on manual labor. Conversely, HDPE sorting lines might be simpler but require more robust machinery for handling rigid materials. Thus, sorting system costs are largely driven by the resin form (rigid versus film) and desired purity levels.

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B. Size Reduction: Customizing Shredders for Optimal Performance

Proper size reduction is essential before washing and extrusion. HDPE and LDPE require different shredder designs due to their distinct mechanical behaviors.

HDPE Size Reduction

Rigid HDPE items (bottles, crates, pipes) require robust shredders with high-torque motors, durable blades, and heavy-duty construction. Single-shaft shredders offer precise particle control, while dual-shaft shredders cater to higher throughput and tougher materials. This heavy-duty requirement results in higher upfront costs and operational expenses related to blade wear.

LDPE Size Reduction

LDPE films are challenging because they easily wrap around rotors, causing jams and downtime. Shredders designed specifically for LDPE films feature specialized rotors, anti-tangling mechanisms, and precise blade configurations. Sometimes, densification or agglomeration processes precede shredding to improve feed consistency. Although LDPE shredders require lower cutting force, they incur higher costs due to their sophisticated design features.

Cost Implications of Size Reduction

HDPE shredders demand higher initial investments due to robust construction and power requirements. LDPE shredders, while less powerful, have additional design complexities, potentially making them equally expensive or more so in certain applications. Blade maintenance is an ongoing operational expense for both resins.

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C. Washing and Decontamination: Ensuring Purity Through Tailored Solutions

Effective washing is crucial for contaminant removal, which varies significantly between HDPE and LDPE recycling processes.

HDPE Washing Systems

HDPE requires intensive washing to remove adhesives, residual products (foods, oils), dirt, and label residues. Friction washers, combined with float-sink tanks, efficiently remove these contaminants. Some systems incorporate caustic chemical treatments and high-pressure sprays for enhanced cleaning effectiveness.

LDPE Washing Systems

LDPE films, particularly agricultural films, have a higher contamination load (soil, oils, chemicals) and require more complex, multi-stage washing processes. These systems may involve pre-washing, multiple friction washing stages, and hot washing (heated water with detergents) for stubborn contaminants. LDPE’s large surface area and layered nature increase the difficulty and cost of thorough cleaning.

Cost Implications of Washing

LDPE washing processes often have higher capital and operational costs due to the complexity, energy use (hot washing), and extensive water treatment requirements. HDPE washing is generally simpler and less expensive, although wastewater treatment remains significant for both resins.

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D. Melting and Extrusion: Precision in Temperature and Screw Design

Melting and extrusion convert plastic flakes into pellets, and the distinct melting characteristics of HDPE and LDPE significantly influence extruder design.

HDPE Extrusion

HDPE melts at higher temperatures (120–180°C, occasionally up to 280°C), requiring robust heating elements, durable screw/barrel materials, and effective insulation. Single-screw extruders are typical, although twin-screw designs may be used for enhanced mixing.

LDPE Extrusion

LDPE has a lower melting point (105–115°C), necessitating precise temperature control to avoid degradation. Due to its branched structure and lower viscosity, LDPE may require specialized screw designs or double-stage single-screw extruders for intensive filtration, homogenization, and degassing, especially in highly contaminated films.

Cost Implications of Extrusion

HDPE extruders generally have higher energy consumption due to elevated temperatures, leading to greater operational costs. LDPE extruders might have lower melting energy costs but potentially higher initial capital investments due to specialized temperature controls and double-stage setups required for high-quality pellet production.

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E. Drying and Pelletizing: Ensuring Pellet Quality Through Customized Processes

Drying efficiency and pelletizing methods directly impact final product quality, with unique challenges presented by each resin.

HDPE Drying and Pelletizing

HDPE flakes undergo mechanical centrifugal drying followed by hot air drying to achieve low moisture content. Strand pelletizing is typical for HDPE, providing simplicity, reliability, and cost-effectiveness.

LDPE Drying and Pelletizing

LDPE films trap significant moisture, requiring more extensive drying (mechanical dewatering plus thermal drying), increasing energy and equipment costs. Water-ring pelletizers, often preferred for LDPE, handle low viscosity and stickiness effectively but involve higher initial investment compared to strand pelletizers.

Cost Implications of Drying and Pelletizing

LDPE systems incur higher costs for drying due to higher moisture retention and complexity. Water-ring pelletizers, typically used for LDPE, involve greater capital expenditures compared to HDPE’s simpler strand pelletizing setups.

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Summary of Key Machinery Considerations

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결론

Understanding the unique properties of HDPE and LDPE is essential when designing or selecting recycling machinery. Optimizing these choices based on resin characteristics ensures efficient operations, high-quality recycled outputs, and cost-effective recycling solutions.