Achieving high currents on PCBs with fine-pitch SMD components

March 28, 2011 // By Peter Mauer
Peter Mauer, the head of electronics design for Semikron Elektronik explains how to achieve high currents on PCBs with fine-pitch SMD components.

In switched-mode power supply systems or other circuits used in power electronics, the demand for control circuitry to use finepitch SMD components is ever increasing. At the same time, however, high currents of more than 100A will be present across the printed circuit board. Product developers face the challenge of finding a suitable yet financially viable solution.

In power electronic systems, the PCBs used often involve challenging technical requirements that force product developers to come up with particularly creative solutions to meet these requirements. Engineering compromises in key areas have to be made, since the sensitive control circuits normally have to use standard inexpensive SMD components. This calls for fine-pitch structures for the wiring and land pattern for the components, microcontroller and FPGAs.

Fine-pitch SMD structures are now easily achieved by the majority of PCB manufacturers for copper thicknesses in the signal layers up to 35µm – see figure 1. By way of contrast, to achieve the high currents needed for a MiniSKiiP module, i.e. to achieve 120 Amps in 35µm technology, either extremely wide wiring or copper surfaces would be needed to keep heat build-up at bay.


Fig. 1: Normal 35µm stackup design.

For such thicknesses, it would be virtually impossible for product designers to comply with clearance specifications if the PCB is to be small in size and, for cost reasons, the number of layers is to be kept to a minimum. The use of standard 35µm technology can therefore be ruled out here; instead, new solutions are required. Possible compromises might be to use thick copper or wirelaid technology.

Thick cooper stackup design

To achieve a satisfactory width for the individual high-current tracks, the stackup design has to be altered while the cross-sectional area of the conductor remains unaltered. If, instead of 35µm-thick copper, the layer thickness for the outer and inner layers is increased to 70µm and 105µm, respectively, suitable conductor widths can be achieved –
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