Abstract: Methods, systems and computer program products for controlling plating pulse rectifiers are provided by identifying one of the plurality of plating pulse rectifiers as a master plating pulse rectifier and identifying at least one of the plurality of plating pulse rectifiers, other than the master plating pulse rectifier, as a slave plating pulse rectifier. A recipe comprising a pulse pattern is downloaded to the master plating pulse rectifier and the slave plating pulse rectifier. A synchronization signal is transmitted from the master plating pulse rectifier upon initiating the pulse pattern of the recipe to the at least one slave plating pulse rectifier so as to cause the slave plating pulse rectifier to initiate the pulse pattern of the downloaded recipe. Plating pulse rectifiers suitable for use as master/slave plating pulse rectifiers and systems incorporating such plating pulse rectifiers are also provided.

Abstract: A power conditioner interfaces a load to a fuel cell 10 that produces a low voltage that varies with the load. A dc-to-ac inverter 16 operates with a low voltage input provided by a dc bus 14. When a positive step load change occurs, a low voltage battery 22 provides power equal to the step change until the fuel cell 10 is able to provide enough power to support the entire load. The power from the battery 22 is supplied to the varying dc bus 14 through a boost converter 12. When very large positive load step changes occur, the battery can feed power to the dc bus through diode D1, rather than through the boost converter. Diode D1 does not need to be used, but its use allows the boost converter to be sized for common load changes rather than for the maximum possible load change (such as might be seen during a faulted output). A buck converter converts the variable voltage on the dc bus 14 to the appropriate float charging voltage of the battery.