Few markets face greater risk than the electronics industry.
That’s why organizations like UL (Underwriters Laboratories) exist. UL evaluates 70+ wire and cable categories worldwide for safety, performance, and use of ethical materials. By following the right UL wire specifications for your specific needs, you can avoid retesting and redesign, improve product safety, and go to market sooner.
These are the UL wire standards that matter most to industrial electronic designs:
There’s also a dedicated UL 758 standard for appliance wiring we’ll cover below.
It’s challenging to sort through the hundreds upon hundreds of UL wire types, plus the array of UL tests for various use cases.
|
Style |
Type |
Temp. Rating |
Voltage Rating |
AWG |
Insulation Thickness |
Insulation Material |
Uses |
|
UL 1007 |
Hookup |
80°C |
300V |
30-16 |
1/64 |
PVC |
Internal wiring for panels, motors, transformers, switchboards, & circuits |
|
UL 1015 |
Hookup |
80-105°C |
600V |
28-9 |
1/32 |
PVC |
Internal wiring of panels, meters, motors, & transformers |
|
UL 1061 |
Hookup |
80°C |
300V |
30-16 |
0.009" |
PVC (semirigid) |
Bookkeeping & time-recording equipment. Must be protected inside the equipment chassis |
|
UL 1569 |
Hookup |
110°C |
300V |
24-16 |
1/64 |
PVC |
Internal wiring of household electronic appliances |
|
UL 2464 |
Jacketed multiconductor |
80°C |
300V |
30-16 |
0.011” |
PVC |
Measurement & control table in production lines, HVAC, etc. |
|
UL 2919 |
Multiconductor with non-integral jacket |
80°C |
300V |
40-22 |
0.03” |
PP |
Computer connection, datacom |
|
UL 3173 |
Hookup |
125°C |
600V |
26-9 |
0.032” |
XLPE |
Appliances; hookups for control panels, transformers, coils, & motors |
|
UL 4511 |
Silicone multiconductor w/ non-integral jacket |
200°C |
600V |
20-2 |
N/A |
TPE |
Applications prone to high temps, UV, and mechanical abuse (factory, baking, heating, & lighting systems) |
|
UL 4535 |
Shielded silicone multiconductor w/ non-integral jacket |
150°C |
600V |
20-2 |
0.006” |
Silicone |
Same as UL 4511 |
AWG (American wire gauge) is important to keeping the integrity and performance of the wire on track. For example, excessive current flow can damage an amplifier, while a lack of voltage could prevent optimal performance.
Insulation thickness plays a huge role in a cable’s electrical performance. A thicker insulation layer blocks the heat radiation that can short-circuit or burn a cable. In general, the more electrical power your application needs, the thicker cable insulation you’ll need.
Insulation material determines the level and type of protection a wire receives. Depending on the application, wire insulation may need to resist extreme temperatures, flames, moisture, chemicals, mechanical stress, or other factors.
We’ll cover temperature and voltage ratings separately below.
UL 758 deserves its own section because it’s a big part of so many industrial wiring solutions. This standard is solely for appliance wiring material (AWM) in factory and production settings, laying out specs for suitable single-conductor, multiconductor, and fiber-optic materials. The wiring is usable:
All wires in this category can withstand at least 60°C heat, though some can survive in much hotter climates.
Appliance wiring material isn’t just for factories. It’s a category that covers a huge swath of wire and cable products.
|
Styles |
Conductor |
Jacket & Insulation |
|
1000-1999 & 10000-19999 |
Single |
Thermoplastic insulation |
|
2000-2999 & 20000-29999 |
Multi |
Thermoplastic insulation & jacket |
|
3000–3999 |
Single |
Thermoset insulation |
|
4000–4999 |
Multi |
Thermoset insulation & jacket |
|
5000–5999 |
Single & multiple |
Fluoropolymer, thermoset |
UL assigns a different AWM number for each approved wire and cable type and publishes a “style page” (example here) outlining the build of that product. The information provided includes voltage range, temperature rating, insulation type and thickness, shielding, and conductor stranding.
Now, on to the key specs to watch out for in evaluating wires:
Unsurprisingly, voltage rating is one of the most important UL wire specs for evaluating suitability for a particular application.
Voltage rating indicates the maximum continuous current a wire can carry without sustaining damage or becoming a safety hazard.
The rating is based on:
Ignoring a wire’s voltage rating can result in overheating, degraded insulation, and other safety and performance issues.
The spark test is a well-known way to measure a connection’s safety. This inline voltage check typically happens during the manufacturing and rewinding phases of a cable’s life. It’s primarily used for low-voltage insulation and medium-voltage nonconductive jacketing and sheaths.
All UL-rated wires carry a temperature rating for dry locations. Some have a second rating for temperature in wet locations.
Wire temperature ratings determine the maximum how hot a wire’s working environment can be without it degrading or becoming a fire hazard.
UL uses two main criteria for wire thermal ratings:
UL uses a variety of testing methods to determine wire temp ratings:
The higher its temperature rating, the better a wire is at withstanding heat. can safely withstand. However, using a wire with a rating of 105°C can be a waste of money if your project’s end-use environment will never surpass 60°C.
A burning wire is, obviously, pretty problematic. They can produce a surprising amount of:
UL can provide two types of fire tests for cables and busways:
UL’s flammability standards for wiring products is a bit of a tangled mess. Your application will determine which ones you should worry about:
It’s rare that UL rates every industrial wire for every situation, because some products are clearly not intended for those situations.
Depending on your project, you may need to meet more niche UL wire and cable standards for these environmental factors:
Material type and thickness of protective layers are the top factors in a wire succeeding or failing in these environments.
Electric industrial wires couldn’t be further from “one-size-fits-all.” They serve nearly every market in existence, so there are a wide variety of standards necessary to cover the seemingly endless use cases.
Some key standards by wire type include:
|
Type |
Application |
|
|
Communications cables |
Telecom |
|
|
Cordsets, supply to power cords |
General indoor use, hospital-grade attachment plugs & cord connectors |
|
|
Below- and above-ground power cables |
Service entrances, wet and cool environments |
|
|
Medium-voltage power cables |
Utilities, engineering, energy, construction |
|
|
Electrical power, control, & tray cables |
Instrumentation, cable trays, raceways |
|
|
Fiber-optic cable |
HVAC, control, communications |
|
|
Multi-point interconnection power cable assemblies < 600V |
Industrial machinery, indoor use, cable fittings |
|
|
Assemblies, feeder-tap systems, feed-through connectors, multi-outlet fittings, panel-mount fittings, splitters < 600V |
Industrial controls |
|
|
Data & signal cables (up to 1,000V) |
Electric vehicle charging stations |
|
|
Low-voltage battery cable |
Surface vehicles |
|
|
Photovoltaic wire (600-2,000V) |
Solar panels |
There are many, many other obscure UL standards for highly specific use cases. All the way down to Christmas lighting.
There are also UL wire standards specifying certain traits of a component(s) of the cable. These determine the materials, dimensions, and other qualities suitable for your wire application:
|
Trait |
What’s It Cover? |
Where Does It Matter? |
|
|
Thermoset insulation |
Flame, smoke, & toxicity emissions; voltage rating; max conductor temp; number of insulated conductors |
Circuits for populated and confined medical, transportation, & entertainment spaces; anywhere with strict specs for emissions levels |
|
|
Flexibility |
General physical properties, conductors, insulation, jacketing, electrical properties, required tests (different for each cable type), markings |
Elevators, service cords, heaters, ovens & dryers, lighting, electric vehicles |
|
|
Thermoplastic insulation |
Flame, smoke, conductor, & insulation testing |
Single-conductor, 600V wires for conduit and cable trays for services, branch circuits, & feeders |
Industrial wire labels help users determine the product’s specs before installation.
Different wire types come with different requirements for their marking – both what’s displayed and where it’s displayed.
This list of UL standards labels includes many for the wiring of appliances, control panels, telecom equipment, and more.
Some wires may have markings for multiple Type designations. This means UL has approved their use in all Type designations on the label.
Boasting a “UL-recognized component” mark on your wire assemblies doesn’t automatically make it safe and effective for your product. Carefully choose components that meet all of your project’s specs and requirements. The top factors in designing a UL-friendly product are temperature resistance, flammability, and voltage capacity – and whether your components will place nicely in these environments.
Pair what you’ve learned so far with the experience of an established distributor (bonus points if it also has manufacturing expertise). The good ones will recommend products that are sufficiently rated for your project, yet don’t inflate your bill of materials cost.
To continue your own research, check out our full resource center: