The rigid structure of a shampoo bottle and the stretch of a grocery bag may seem like they’d be made from very different materials with contrasting traits, but both are thanks to one type of thermoplastic: low-density polyethylene. You might already be aware of polyethylene and its unique set of mechanical and physical traits, but there is more than one type — making it easy for manufacturers to find the right fit for the products they’re looking to produce.
Low-density polyethylene has its own list of handy characteristics. Here’s what separates it from other kinds of polyethylene and the types of applications you’ll find it’s commonly used.
What Is Low-Density Polyethylene (LDPE)?
Low-density polyethylene is a type of thermoplastic in the polyethylene family. It’s formed of long chains of ethylene molecules called monomers. Its chemical formula is (C2H4)n — the same as high-density polyethylene. Their differences lie in density, as their names suggest. Once LDPE is created, it’s typically flexible and transparent in color.
It’s a common choice for manufacturing plastic goods like cling wrap and juice containers because it’s corrosion-resistant, flexible, durable, and low-cost. On products, you’ll recognize it through the number four in a triangle (usually on the bottom or side of the item).
How LDPE Is Made
To make low-density polyethylene, you’ll need to call on the radical polymerization process. This involves extreme heat (up to 570 degrees Kelvin) and an immense amount of pressure (up to 3,000 atm). First, the raw petroleum-based materials are broken down into small molecules, then the ethylene gas is separated and funneled into a reactor.
In the reactor, it’ll come into contact with an initiator like oxygen or organic peroxide. Then, the polymerization will begin.
The image beneath shows how polyethylene and ethylene molecules and their chemical formulas look visually.
Applications of Low-Density Polyethylene
The stretchy but strong nature of low-density polyethylene makes it a great candidate for materials that need to hold heavier weights without snapping or disintegrating. That’s why LDPE is used for things like grocery bags or six-pack rings for soda. Here are a few other ways that you’ll find LDPE implemented:
- Juice containers
- Cling wrap and films
- Bags (like those used for groceries or food)
- Trays
- Six-pack rings
- Tubing
- Prosthetics
- Ice cream lids
- Laminates
Advantages and Disadvantages
There are good reasons to use low-density polyethylene, but depending on the type of product you’re manufacturing, there are also disadvantages to be wary of.
Advantages:
- Flexible: LDPE bends, stretches, and has low crystallinity.
- Moisture resistance: LDPE has no problem deflecting moisture and water.
- Impact and chemical resistance: LDPE won’t break down if it’s exposed to diluted or concentrated chemicals.
- Low price point: LDPE is fairly cheap to produce and can be recycled.
Disadvantages:
- Cracking and lower strength: LDPE might crack or break when it has to hold heavier objects.
- Has a Max Temperature: LDPE can handle pretty hot temperatures, but above 221 degrees Fahrenheit, it will start melting.
- High gas permeability: Gasses like carbon dioxide can easily slide through LDPE.
- Poor UV resistance: LDPE struggles to keep its shape, color, and integrity when it’s exposed to UV rays.
- Recycling can be tricky: LDPE is recyclable, but not every product made of it can go in standard home or business recycling containers. It will need to be sorted properly or specially processed at particular facilities, especially for softer, more flexible items like cling film.
Low-Density vs. High-Density Polyethylene
High-density Polyethylene is another material Xometry offers in its molding and machining processes. There are a few differences between low-density and high-density polyethylene, but let’s start with similarities. Both are types of polyethylene, and each has flexibility, chemical resistance, and decent strength. They’re also both relatively affordable to create and manufacture.
Differences arise in their polymer chains and resulting weights and properties. LDPE has a looser molecular structure, giving it its signature flexibility. HDPE’s monomers are tightly packed together, so it’s not as flexible as LDPE.
You probably won’t be surprised to learn that HDPE is stronger and more durable than LDPE. It’s a great choice for industrial applications that need a certain level of stiffness and chemical resistance. Still, LDPE has its perks. It can provide you with an elasticity that its high-density counterpart can’t provide.
To learn more, see our in-depth guide on High Density Polyethylene (HDPE).
Here are a few other commonly asked questions when it comes to the nature of low-density polyethylene:
Summary
Xometry provides a wide range of manufacturing capabilities including CNC machining, 3D printing, injection molding (using LDPE), laser cutting, and sheet metal fabrication. Get yourinstant quotetoday.
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Kat de Naoum
Kat de Naoum is a writer, author, editor, and content specialist from the UK with 20+ years of writing experience. Kat has experience writing for a variety of manufacturing and technical organizations and loves the world of engineering. Alongside writing, Kat was a paralegal for almost 10 years, seven of which were in ship finance. She has written for many publications, both print and online. Kat has a BA in English literature and philosophy, and an MA in creative writing from Kingston University.
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