Isolated DC/DC Converters

Although DC/DC converters exist without input-to-output isolation, most DC/DC converters use an internal transformer, and the output is electrically (galvanically) isolated from the input. The separated output can be used to provide either a floating power source or to generate different voltage rails and/or dual polarity rails (Figure 2). Since the output is isolated from the input, the choice of reference voltage for the input or output side can be arbitrary (Figure 3); for example, a DC/DC can be used to change the voltage polarity (e.g. -5V out from +5V in), add a voltage (e.g. +12V from a +5V supply) or generate a dual output from a single supply (e.g. ±5V from a 12V battery). This feature makes DC/DC converters very versatile. Having outputs that are floating with respect to the input is also quite useful; the isolation breaks ground loops and thus eliminates noise in electrical systems, the output polarity can be freely chosen, and of course the isolation barrier is an important safety element, as a safeguard against electric shock or short circuit hazards.

There are three main classes of isolation:

• Operational or Functional (the output is isolated, but there is no fault protection)
• Basic (the transformer offers single fault protection)
• Reinforced (two independent means of insulation that offer double fault protection)

So how do these definitions translate into practical transformer construction?

There is also another way of making a basic insulated transformer, namely the potted core. In this method of construction, the core and one winding are placed inside a plastic pot which is filled with epoxy. A lid is fitted and then the second winding is wound around the whole construction through the hole in the middle. This type of construction is used in the RP series.

With reinforced isolation, the input and output windings are separated by at least two separate independent physical barriers (Figure 8), and the transformer has increased creepage and clearance dimension requirements compared to basic isolation. Examples of RECOM converters with reinforced isolation are the RxxPxx/R, REC6-RW/R and REM medical grade series.

Clearance is the shortest distance between two points measured point to point (arcing distance). Creepage is the shortest distance between two points measured by following the surface (tracking distance).





Note: Creepage and clearance are based on the sum of the input and output voltages (e.g. 24V±10% in, 5V out = 31.4VDC working voltage) and not the primary power supply voltage, unless the converter is specified for a particular working voltage (e.g. 250VAC).

The internal clearances and creepages within the transformer also depend on the construction:

Functional designs have internal clearances equal only to the thickness of the transformer wire lacquer, e.g. 0.016mm. The bridged transformer construction has creepage and clearance equal to the thickness of the separation bridge (2mm), whereas the pot core construction has a clearance equal to double the wall thickness of the plastic pot (0.5mm + 0.5mm), but a creepage of a minimum of 3mm.

Reinforced transformers using triple insulated wires (TIW) or fully insulated wires (FIW) can meet the requirements for reinforced insulation within the transformer, using only the wires themselves, but still need to meet clearance requirements between the transformer and adjacent components. The standard creepage and clearance separations also apply to all the other components; for example, the opto-coupler and any EMC capacitors bridging the isolation gap ...