With so many cable types available, choosing the right one isn’t always straightforward. Even after narrowing your needs down by function, you’re still left with dozens of material options for insulation and jacketing.
Depending on the environment, your project might need protection from corrosion, abrasion, moisture, or extreme temperatures. You also have to weigh cost and supplier availability on top of that.
A quick cable jacket material comparison before ordering helps set your industrial assembly up with the right type of protection.
Cable jacketing is the outer layer that protects all other components from moisture, chemical, and mechanical hazards. Jackets’ side jobs include adding flexibility for installation and color-coding for easy identification.
Cable insulation is the non-conductive covering attached to bare wires to separate conductors from each other, both physically and electrically. It not only protects against current leakage; it also offers a second layer to fight heat and moisture.
A cable’s insulation material type can influence the overall electrical properties of the cable. For example, an insulation’s thickness determines voltage rating, and its ability to withstand high temperatures means it can carry more current without failing.
Jacketing and insulation share many materials, most of them derivatives of rubber or plastic. However, not all insulation materials can be used for jacketing.
There are three main branches of cable jacket and insulation material: thermoplastic, thermoset, and fluoropolymer. (We’ll discuss them further below.) Each has its own family of materials, and manufacturers offer product variations on each material.
It’s a lot to take in. Above all else, watch for these traits that may influence performance in your application.
|
Property |
Performance |
|
Affordability |
Medium |
|
Heat resistance |
High |
|
Cold resistance |
Medium-High to High |
|
Flexibility |
Medium-High to High |
|
Durability |
Low to High |
|
Stripability |
Low to High |
Thermoset materials consist of basic polymers that are cured or vulcanized to form a cross-linked structure. Once a thermoset has been cured, you can’t remold it, which makes it a more heat-resistant jacketing material in high-load and short-circuit situations.
This quality makes thermoset cables the popular choice for circuits prone to a conductor overload.
Other benefits include:
Thermoset jacketing and insulation is common in:
|
Neoprene (Polychloroprene) |
➕ Resists aging due to sunlight and water |
|
|
Ethylene Propylene Rubber (EPR) |
➕ Excellent heat, abrasion, and corrosion resistance |
|
|
CPE – Thermoset Version |
➕ Excellent physical properties |
|
|
Thermoplastic Rubber (TPR) |
➕ Resistant to a broad range of temperatures |
|
|
Styrene Butadiene Rubber (SBR) |
➕ Better hot/cold resistance than neoprene (-55 to 85 °C) |
|
|
Silicone |
➕ Flame retardance meets NEC cable jacket ratings |
|
|
Fiberglass |
➕ Survives in temperatures up to 482 °C. |
|
|
Chlorosulfonated Polyethylene (CSPE) |
➕ Good chemical, abrasion, oil, and UV resistance |
|
|
Ethylene Propylene Diene Monomer (EPDM) |
➕ Low conductivity |
|
|
Property |
Performance |
|
Affordability |
High |
|
Heat resistance |
Low to Medium-High |
|
Cold resistance |
Low to High |
|
Flexibility |
Low to Medium-High |
|
Durability |
Low to High |
|
Stripability |
Medium-High to High |
Thermoplastics is a branch that includes a few well-known options: PVC and polyurethane cable jackets.
A thermoplastic is a material that changes hardness during heating and cooling. In extreme-temperature applications, this could mean the cable becomes deformed, decreasing its physical properties.
On the plus side, these cheaper materials are often easier to strip, which makes large-volume application more efficient (i.e. for automation equipment).
Other benefits:
Thermoplastic jacketing and insulation is common in:
|
PVC |
➕ Widely available |
|
|
Thermoplastic Polyurethane (PUR/TPU) |
➕ Halogen-free |
|
|
Polyethylene (PE) |
➕ High insulation resistance |
|
|
Thermoplastic Elastomer/Rubber (TPE/TPR, Santoprene) |
➕ Halogen-free |
|
|
Chlorinated Polyethylene (CEP) - Thermoplastic Version |
➕ Excellent moisture, UV, & oil resistance |
|
|
Property |
Performance |
|
Affordability |
Low |
|
Heat resistance |
High |
|
Cold resistance |
Medium-High |
|
Flexibility |
Medium-High |
|
Durability |
High |
|
Stripability |
Medium-High |
This family of plastic resins is known for its toughness. For example, fluoropolymer insulation boasts high resistance to acids, solvents, and bases that corrode cables.
Other benefits include:
Fluoropolymer jacketing and insulation is common in:
|
Perfluoroalkoxy (PFA) |
+ Enhanced electrical efficiency due to low dissipation factor |
|
|
Polytetrafluoroethylene (PTFE) |
+ Exceptional resistance to chemicals, oil, and moisture |
|
|
Ethylene Tetrafluoroethylene (ETFE) |
+ Excellent corrosion resistance |
|
|
Ethylene Chlorotrifluoroethylene (ECTFE or Halar) |
+ Superior strength |
|
|
Fluorinated Ethylene Propylene (FEP, Variation of Teflon) |
+ Excellent electrical insulation properties |
|
|
Polyvinylidene Fluoride (PVDF) |
+ Low cost |
|
Performance-minded engineers usually stick with thermoset cables in applications where failure isn’t an option. Some of the most extreme environments may require a unique fluoropolymer material.
That said, there are other, less-common materials under all three main branches. Basically, there’s a solution for any industrial application you could dream up.
Not every cable and wire manufacturer offers all of these materials. However, manufacturers who also offer distribution services can source the cable types they don’t make in-house.
Start with our free electronic component guide to make safe choices about jacketing, insulation, and sourcing.
This article was originally published in May 2023 and was recently updated to reflect current industry trends.