A slide rail structure for fixing a power supply to a machine frame is disposed between the machine frame and the power supply. The machine frame includes at least two longitudinal left racks and at least two longitudinal right racks at two sides thereof. The slide rail structure includes two inner slide rails and two outer slide rails. One inner slide rail is laterally fixed to the two left racks, and the other inner slide rail is laterally fixed to the two right racks. The two outer slide rails are laterally locked to two sides of the power supply, respectively. The outer slide rails are slidably connected to the inner slide rails, respectively. Through the slide rail structure, the power supply won't sway left and right in the machine frame, thereby enhancing the stability of the power supply.

A power converter includes: a plurality of semiconductor devices; a heat receiving plate; and a first partition member. The semiconductor devices constitute a power conversion unit. The heat receiving plate includes a first surface supporting the semiconductor devices. The first partition member is fixed to the heat receiving plate and partitions the semiconductor devices.

A power supply structure comprises a housing, a socket and a fan. The housing has a main housing, a terminal housing and a front panel, wherein the terminal housing connected with the main housing. The fan and the terminal housing disposed on one end of the main housing, and the fan attached to the front panel. The socket arranged in parallel with the fan and connected to the terminal housing.

The present application provides a power supply cabinet, comprising a first power supply region and a second power supply region including at least one slot for receiving a first power supply module and a second power supply module respectively, a mode switching unit for outputting a mode signal to the first power supply module and the second power supply module, and a position setting unit for outputting a position signal to the first power supply module and the second power supply module. Input sides of the first power supply module and the second power supply mode are electrically connected to a first power supply and a second power supply. The power supply cabinet selectively operates in a first power supply mode (e.g. N+N mode) or a second power supply mode (e.g. N+1 mode) depending on the mode signal or types of the power supplies.

A power converter includes an outer housing formed of dielectric material and including a low voltage compartment and a high voltage compartment is disclosed. The power converter also includes a low voltage DC-to-AC converter disposed in the low voltage compartment, a first coil in the low voltage compartment, a first conductive shield element lining an outer wall of the low voltage compartment, the first conductive shield element being electrically coupled to an electrical input of the DC-to-AC converter and a second conductive shield element lining an outer wall of the high voltage compartment.

A power module for medium and high-voltage frequency converter and a frequency converter comprising same. The power module has a three-phase alternating current input and a single-phase alternating current output, and comprises a circuit board (100), a rectifying module (120), a capacitor bank (130), and an inverting module (140), wherein the rectifying module, the capacitor bank and the inverting module are all mounted on the circuit board. The power module has a compact structure and is convenient to cool.

A Variable In Line Voltage Booster includes a housing; at least one set of input connectors; at least one set of output connectors; a plurality of power converters carried by at least one power converter board and coupled between the at least one set of input connectors and the at least one set of output connectors and operable to adjust a voltage received via the at least one set of input connectors to supply a voltage via the at least one set of output connectors; and a control board carrying a set of control circuitry, the control circuitry communicatively coupled to control the plurality of power converters. The housing may be rack mountable, and may include inlet vents and exhaust vents, either with or with fans. A control board may be spaced from one or more power converter board, which carry power electronics (e.g., MOSFETS, BJTs) via one or more posts

The present application provides a power supply cabinet, comprising a first power supply region and a second power supply region including at least one slot for receiving a first power supply module and a second power supply module respectively, a mode switching unit for outputting a mode signal to the first power supply module and the second power supply module, and a position setting unit for outputting a position signal to the first power supply module and the second power supply module. Input sides of the first power supply module and the second power supply mode are electrically connected to a first power supply and a second power supply. The power supply cabinet selectively operates in a first power supply mode (e.g. N+N mode) or a second power supply mode (e.g. N+1 mode) depending on the mode signal or types of the power supplies.

A high voltage electrical unit is installed above a floor of a vehicle between left and right seats. A bracket is fixed on the floor between the left and right seats, and the high voltage electrical unit is fixed on a bracket top plate of the bracket. A protect cover for covering the high voltage electrical unit is fixed on the bracket. Strength of the protect cover against a lateral load is made higher than strength of the bracket against the lateral load.

In a power conversion device, a power conversion unit includes a single-phase inverter on a secondary side of a resonant type converter that has an input of a direct current. A power conversion unit group is configured by connecting outputs of the single-phase inverters of a plurality of power conversion units in series. Respective phases of three phase alternate current are formed with the three power conversion unit groups housed in a power conversion device housing. The plurality of power conversion units constituting the power conversion unit group are disposed along a longitudinal direction of the power conversion device housing. The respective three power conversion unit groups are disposed at an upper stage, a middle stage, and a lower stage in a height direction of the power conversion device housing. The power conversion device housing has one end side in the longitudinal direction as output terminals of the three power conversion unit groups. The power conversion device housing has the other end side in the longitudinal direction where terminals of the three power conversion unit groups are connected in common.