HDPE CPR 100 natural (High-Density Polyethylene) is an engineering polymer that has the strength-to-density ratio at a maximum level. The excellent toughness and flexibility of HDPE, combined with cost-effectiveness, make it highly in demand in numerous industrial and commercial applications. It finds applications where the requirement of mechanical strength along with chemical resistance is involved
MFI (190/5): 0.25 g/10 min
The Melt Flow Index (MFI) is an important parameter that indicates the ease with which the material flows during the molding process. With an MFI of 0.25 g/10 min, HDPE CPR 100 is a relatively slow-flowing material, which makes it ideal for producing strong, durable products that require high mechanical performance
Tensile Strength at Yield (Tensile@y): 22 MPa
The tensile strength at yield is a measure of the maximum stress that the material can withstand while being stretched before it begins to deform permanently. A tensile strength of 22 MPa ensures that HDPE CPR 100 has adequate resistance to breakage under tensile stress, making it suitable for applications requiring high strength
Elongation at Break (Elongation@B): Minimum 1000%
Elongation at break measures the material's ability to stretch without breaking. With a minimum elongation of 1000%, HDPE CPR 100 shows excellent flexibility and stretchability, hence it is ideal for use in products such as plastic films, pipes, and containers requiring elasticity
Tensile Strength at Break (Tensile@b): Minimum 30 MPa
This parameter indicates the strength of the material at the point of breaking under stress. HDPE CPR 100 is highly resistant to tearing and cracking, which is crucial in applications involving heavy mechanical loads, with a minimum tensile strength of 30 MPa at break
Hardness: 60 (Shore D)
The hardness of HDPE CPR 100 is at 60 Shore D. This degree of hardness signifies resistance against indentation and scratching. That level of hardness balances stiff and flexible characteristics to be practical for objects that should maintain the shape and structure but will also withstand wear and tear.
Melting Point: 130°C
The melting point is an important parameter for determining the thermal properties of the material. With a melting point of 130°C, HDPE CPR 100 can be used for applications that are moderately exposed to high temperatures, such as piping systems or industrial containers
OIT (Oxidation Induction Time): Minimum 30 minutes
Oxidation Induction Time (OIT) measures the material's resistance to thermal degradation in the presence of oxygen. A minimum OIT of 30 minutes ensures that HDPE CPR 100 natural is stable and resistant to oxidation, even in demanding environments, which contributes to its longevity
Applications: HDPE CPR 100 natural can be used in a variety of industries
Packaging: Because of the high tensile strength and its flexibility, HDPE CPR 100 natural is perfectly suited for making durable packing materials, like containers, bottles, etc
Piping Systems: Its mechanical stress-resistance and its pressure-resistance capability make HDPE CPR 100 natural ideal in water and gas piping systems
Agriculture: It is used in the irrigation system, greenhouse films, and agricultural tanks due to its durability and resistance to weather.
Automotive: The high impact strength and low weight of HDPE CPR 100 natural make it a preferred material in automotive parts manufacturing, thus contributing to fuel efficiency
Construction: HDPE CPR 100 natural is widely used in the construction industry for producing geomembranes, drainage pipes, and barrier materials due to its robustness and resistance to harsh environmental conditions
