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June 12, 2024
Due to increasing energy regulations, most people are familiar by now with the long life spans and energy savings associated with LEDs, or light-emitting diodes. However, many are not aware that these innovative light sources require specialized devices called LED drivers to operate. LED drivers (also known as LED power supplies) are similar to ballasts for fluorescent lamps or transformers for low- voltage bulbs: they provide LEDs with the electricity they require to function and perform at their best.
LEDs require drivers for two purposes:
LEDs are designed to run on low voltage (12-24V), direct current electricity. However, most places supply higher voltage (120-277V), alternating current electricity. An LED driver rectifies higher voltage, alternating current to low voltage, direct current.
LED drivers also protect LEDs from voltage or current fluctuations. A change in voltage could cause a change in the current being supplied to the LEDs. LED light output is proportional to its current supply, and LEDs are rated to operate within a certain current range (measured in amps). Therefore, too much or too little current can cause light output to vary or degrade faster due to higher temperatures within the LED.
In summary, LED drivers convert higher voltage, alternating current to low voltage, direct current. They also keep the voltage and current flowing through an LED circuit at its rated level.
For the aforementioned reasons, every LED light source requires a driver. However, some LEDs, particularly those designed for household use, contain internal drivers rather than separate, external drivers. Household bulbs usually include an internal driver because it makes replacing old incandescent or CFL bulbs easier. These include LED bulbs with standard screw-in or plug-in bases (E26 / E27 or GU24 / GU10 – see images below) or those that specify a line-voltage (120 volts) input on their datasheet. LEDs that typically require an external driver include cove lights, downlights, and tape lights, as well as certain fixtures, panels, and outdoor-rated lights. These bulbs are often used for commercial, outdoor, or roadway lighting purposes. They typically require a separate driver because it’s simpler and cheaper to replace the driver than the LEDs. Sometimes, LEDs will come equipped with a separate driver. Other times, manufacturer datasheets will specify whether or not an LED requires a separate driver, along with the type of driver it requires if necessary.
When an LED stops operating before the end of its rated lifetime, it can usually be saved if the driver is replaced. Drivers often fail prematurely due to high internal operating temperatures. Battery-like components called electrolytic capacitors are typically the cause of death. Electrolytic capacitors have a gel inside them that gradually evaporates over the lifespan of the driver. High temperatures quicken the evaporation of the gel and shorten the life of the capacitor, causing the driver, and hence your LED, to stop working unexpectedly.
The temperature within the driver correlates to the external temperature on the driver case. A small circle on the label of most LED drivers, called the "TC point," is the hottest point on the driver. This point is usually marked with a temperature and is used to determine the driver’s max operating temperature. If a driver is used at a temperature too close to this limiting temperature, it will have a shorter lifespan than if it were operated at a lower temperature. This is why drivers with higher TC points have longer lifetimes. Drivers must be used at operating temperatures below the TC point (or they must at least contain long-life electrolytic capacitors) to ensure that the driver lifetime exceeds the lifetime of the LED. When an LED is not subject to either of these conditions, drivers can fail and must be replaced. The graph below correlates the lifetime of a typical LED driver to its hotspot temperature.
There are two main types of external LED drivers, constant-current and constant-voltage, as well as a third type of driver called an AC LED driver which will also be discussed. Each type of driver is designed to operate LEDs with a different set of electrical requirements. When replacing a driver, the old driver’s input/output requirements must be matched as closely as possible. Key differences are detailed below.
Constant-current drivers power LEDs that require a fixed output current and a range of output voltages. There will be only one output current specified, labeled in amps or milliamps, along with a range of voltages that will vary depending on the load (wattage) of the LED. In the example below to the left, the current output is 700mA, and the output voltage range is 4-13V DC (volts of direct current).
Constant-voltage drivers power LEDs that require a fixed output voltage with a maximum output current. In these LEDs, the current is already regulated, either by simple resistors or an internal constant-current driver, within the LED module. These LEDs require one stable voltage, usually 12V DC or 24V DC. In the example below to the right, the output voltage is 24V DC, and the output current is a maximum of 1.04A.
AC LED drivers are actually no-minimum load transformers, meaning they could technically operate low-voltage halogen or incandescent bulbs as well. LEDs, however, cannot operate with conventional transformers because conventional transformers were not made to detect the low wattage of LEDs. In other words, LEDs have such a small electrical load that regular transformers do not register that they’re wired to a bulb at all. AC LED drivers are typically used with bulbs that already contain an internal driver that converts the current from AC to DC, so an AC LED driver’s job is to register the low wattage of LEDs and step down the voltage to meet the bulb’s voltage requirements, usually 12 or 24 volts. AC LED drivers are typically used to power 12-24V AC input LED MR16 bulbs, but they can be used for any 12- 24V AC input LED bulb. The LED bulb datasheet must be carefully examined; if the LED bulb requires DC voltage input, it cannot be used with an AC LED driver.
According to the NEC (National Electrical Code), LED drivers should be paired with LEDs that use 20% less than their maximum rated wattage (with the exception of AC LED drivers). Drivers should not be paired with an LED that is at or exceeds the driver’s maximum wattage to avoid overstressing the driver components. For example, if you have a driver that can operate a maximum of 96 watts, it should only operate LEDs that use 77 watts at most (96 x 0.8 = 76.8).
Both constant-current and constant-voltage LEDs and drivers can be made with a dimming capability, though both LEDs and drivers must specify that they are dimmable on the product datasheet for that assertion to be made. If the specs don’t mention dimming at all, it is safe to assume that the product is not dimmable. Dimmable external drivers often require an external dimmer, or other dimming control devices specified on the product datasheet (namely TRIAC, Trailing Edge, or 1-10v dimmers) to work. Since technologies are improving rapidly, it’s best to test specific LED/dimmable driver combinations for acceptable dimming performance before making large purchases if brand-specific dimmer compatibility charts are not available.
Power factor describes how efficiently an LED driver uses electricity. It is calculated by dividing the power being used by the driver (wattage) divided by the product of the input voltage times the current going in (volts x amps). The range for power factor is a decimal between 0 and 1. The closer to 1 the power factor is, the more efficient the driver is. A good power factor is 0.9 or above.
UL Class 2 drivers comply with standard UL1310, meaning output is considered safe to contact and no major safety protection is required at the LED / luminaire level. There is no risk of fire or electric shock. These drivers operate using less than 60 volts in dry applications, 30 volts in wet applications, less than 5 amps, and less than 100 watts. However, these limitations pose restrictions on the number of LEDs a Class 2 driver can operate.
UL Class 1 drivers have output ranges outside UL Class 2 designations. An LED Driver with a UL Class 1 rating has a high-voltage output and safety protection is required within the fixture. A Class 1 driver can accommodate more LEDs, making it more efficient than a Class 2 driver.
IP ratings tell users the environmental protection that a driver’s outer casing provides. The first number specifies protection against solid objects, and the second number specifies protection against water elements. For example, according to the chart below, a driver with an IP67 rating is protected against dust and temporary immersion in water.
1st Digit |
Solid Object Protection |
2nd Digit |
Water Protection |
0 |
Not protected |
0 |
Not Protected |
1 |
Protected against solid objects greater than 50mm (e.g. accidental bump of hand) |
1 |
Protected against vertically dripping water |
2 |
Protected against solid objects greater than 12.5mm (e.g. fingers) |
2 |
Protected against sprays of water when tilted up to 15 degrees vertically |
3 |
Protected against solid objects greater than 2.5mm (e.g. tools and wires wires) |
3 |
Protected against sprays of water when tilted up to 60 degrees vertically |
4 |
Protected against solid objects greater than 1mm (e.g. small wires) |
4 |
Protected against water sprayed in all directions |
5 |
Protected against dust |
5 |
Protected against low-pressure jetting water from all directions |
6 |
Dust tight (total protection) |
6 |
Protected against powerfully jetting water from all directions |
|
7 |
Protected against temporary immersion in water (under 30 minutes) |
|
8 |
Protected against continuous immersion in water |
Consider the physical dimensions of the driver. Make sure it will fit in the area you will place it.
Q & A
Yes, in that they both regulate current. However, if you use a resistor, the current will slowly continue to rise over time. Constant-current drivers are preferable because they are more consistent, efficient, and flexible, especially for high-power LEDs.
In some cases, an external driver can operate more than one light fixture. A driver’s datasheet should always specify how many fixtures it can operate.
What are the differences between TRIAC, Trailing Edge, and 1-10v Dimmers?
TRIAC is the most commonly used and cheapest dimmer. However, they generate undesirable amounts of Electro-Magnetic Interference (EMI).
Trailing Edge (Reverse Phase or ELV) dimmers generate much lower amounts of EMI, but they are more expensive than TRIAC dimmers. Also, in the U.S., most Trailing Edge dimmers require that a neutral wire be run to the dimmer.
0-10V dimmers use low-voltage control wires to dim. This usually means that an extra pair of wires must be connected to every driver the dimming module operates.
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