An inline DC feeder DC/DC voltage step-up harness for photovoltaic solar facilities includes a housing, a plurality of PV input connectors, an at least one PV output connector. The housing incorporates a DC/DC converter, and has an input and an output. The plurality of PV input connectors are operatively connected to the housing at the input. The PV output connector is operatively connected to the housing at the output.

An inline DC feeder DC/DC voltage step-up harness for photovoltaic solar facilities includes a housing, a plurality of PV input connectors, an at least one PV output connector. The housing incorporates a DC/DC converter, and has an input and an output. The plurality of PV input connectors are operatively connected to the housing at the input. The PV output connector is operatively connected to the housing at the output.

The disclosure provides a system of providing power to a chip on a mainboard, including: a first power supply, located on the mainboard, and configured to receive a first voltage and to provide a second voltage; and a second power supply and a third power supply, located on the mainboard, wherein the second power supply and the third power supply are electrically connected to the first power supply; so as to receive the second voltage, the second power supply is disposed at a first side of the chip, the third power supply is disposed at a second side of the chip, the second power supply provides a third voltage to the chip, and the third power supply provides a fourth voltage to the chip.

The disclosure provides a system of providing power to a chip on a mainboard, including: a first power supply, located on the mainboard, and configured to receive a first voltage and to provide a second voltage; and a second power supply and a third power supply, located on the mainboard, wherein the second power supply and the third power supply are electrically connected to the first power supply; so as to receive the second voltage, the second power supply is disposed at a first side of the chip, the third power supply is disposed at a second side of the chip, the second power supply provides a third voltage to the chip, and the third power supply provides a fourth voltage to the chip.

A mounting base can comprise: a group of mounting areas, each mounting area of the group of mounting areas comprising: a respective mechanical connector member of a group of respective mechanical connector members for attaching to a complementary mechanical connector member on each direct-current to direct-current (DC/DC) converter unit of the group of DC/DC converter units, and a respective electrical connector of a group of respective electrical connectors for attaching to a complementary electrical connector on each DC/DC converter unit of the group of DC/DC converter units, a group of electrical conductors attached to the group of respective electrical connectors in each mounting area, and attached to a main connector on the mounting base for connecting to a high-voltage (HV) connector of a main HV supply, and a cooling channel extending in heat conducting contact with the group of mounting areas.

An aspect of the present invention is a voltage supply device including: a controller which outputs a signal indicating any one bus voltage determined by negotiation among a plurality of bus voltages from a power supply circuit to an external device; a reference voltage generation unit which generates a reference voltage corresponding to the signal; a detection voltage output unit which detects the bus voltage and outputs a detection voltage; a comparison unit which compares the detection voltage with the reference voltage; and a switch unit which switches the supply state of the bus voltage to the external device in response to the comparison result.

An aspect of the present invention is a voltage supply device including: a controller which outputs a signal indicating any one bus voltage determined by negotiation among a plurality of bus voltages from a power supply circuit to an external device; a reference voltage generation unit which generates a reference voltage corresponding to the signal; a detection voltage output unit which detects the bus voltage and outputs a detection voltage; a comparison unit which compares the detection voltage with the reference voltage; and a switch unit which switches the supply state of the bus voltage to the external device in response to the comparison result.

A transport climate control system is disclosed. The system includes a compressor, a motor-generator-rectifier machine, a belt drive connected to the motor-generator-rectifier machine and the compressor, at least one condenser fan, at least one evaporator fan, and a DC to DC converter. The motor-generator-rectifier machine connects to the at least one condenser fan, the at least one evaporator fan, and the DC to DC converter. The motor-generator-rectifier machine includes a motor, a low voltage generator connected to the motor, and a rectifier connected to the low voltage generator. The motor-generator-rectifier machine can provide a first low voltage DC power to the at least one condenser fan, the at least one evaporator fan, and the DC to DC converter. The DC to DC converter can convert the first low voltage DC power to a second low voltage DC power that is different from the first low voltage DC power.

A transport climate control system is disclosed. The system includes a compressor, a motor-generator-rectifier machine, a belt drive connected to the motor-generator-rectifier machine and the compressor, at least one condenser fan, at least one evaporator fan, and a DC to DC converter. The motor-generator-rectifier machine connects to the at least one condenser fan, the at least one evaporator fan, and the DC to DC converter. The motor-generator-rectifier machine includes a motor, a low voltage generator connected to the motor, and a rectifier connected to the low voltage generator. The motor-generator-rectifier machine can provide a first low voltage DC power to the at least one condenser fan, the at least one evaporator fan, and the DC to DC converter. The DC to DC converter can convert the first low voltage DC power to a second low voltage DC power that is different from the first low voltage DC power.

A DC transformer circuit is provided. A first end of an energy storage inductor in the DC transformer circuit is connected with a module output pin in a DC transformer module, and a second end of the energy storage inductor is connected to a grounded terminal. Using the DC transformer circuit can thus generate a negative voltage for a display device. Compared to a DC buck-boost circuit adopted in the existing arts, the DC transformer circuit has an advantage of low cost.