27-01-2018, 12:56 PM
Abstract:
To give power to an artificial heart through intact skin, an electricity supply system has been developed and it has been built using a transcutaneous transformer. To understand both high-voltage gain and minimum circulating current, compensation for leakage subsidy on both sides of a transcutaneous transformer is proposed. A frequency zone that feels strong against coupling coefficient and load diversity is identified. In this field, the power converter has the advantages such as zero-voltage switching (ZVS) or zero-current switching of switches (ZCS), high voltage gain, minimum circulating current and high efficiency.
To give power to an artificial heart through intact skin, an electricity supply system has been developed and it has been built using a transcutaneous transformer. To understand both high-voltage gain and minimum circulating current, compensation for leakage subsidy on both sides of a transcutaneous transformer is proposed. A frequency zone that feels strong against coupling coefficient and load diversity is identified. In this field, the power converter has the advantages such as zero-voltage switching (ZVS) or zero-current switching of switches (ZCS), high voltage gain, minimum circulating current and high efficiency.
