A shielding arrangement can be provided for a piece of high voltage equipment spaced from a neighboring object. The piece of high voltage equipment has a first electric potential and the neighboring object has a second electric potential. The shielding arrangement includes a resistor, a shield element for connection to the high voltage equipment via the resistor, and a capacitor connected in parallel with the resistor. A resistance of the resistor and a capacitance of the capacitor together define a time constant in a range of 10 μs-50 ms.

The invention is concerned with an inhibitor module arrangement, a shielding arrangement comprising an inhibitor module and a converter station comprising a converter and a shielding arrangement. The inhibitor module arrangement comprises a first string, a second string, and at least one first inhibitor module (30), where the first string comprises resistors (R1), the second string comprises capacitors (C1, C2, C3), the first string is physically separated from and electrically connected in parallel with the second string and the at least one first inhibitor module (30) comprises a first electrical connection terminal (32) at a first end for connection to a piece of high voltage equipment, a second electric connection terminal (34) at a second end for connection to a first shield element for this piece and a closed interior comprising at least one of the strings electrically connected between the first and the second electrical connection terminals (32, 34).

A power converter path of a modular multilevel power converter includes a multiplicity of modules forming an electrical series circuit. The series circuit includes four groups of modules, of which two successive or sequential groups are disposed one above the other in a tower structure. A modular multilevel power converter with a power converter path is also provided.

A discharge unit of an embodiment includes a drain pan, a discharge portion having an insulation property, a grounded drain piping, and a liquid separation part having an insulation property. The drain pan receives a liquid. The discharge portion is connected to the drain pan and drains the liquid remaining in the drain pan. The liquid separation part prevents the liquid from flowing continuously between the discharge portion and the drain piping.

A switch module for an inverter includes a high-side switch and a low-side switch, each of which has at least one semiconductor switch, wherein the semiconductor switches are attached to a flat substrate; a DC input connection with a positive DC input contact and a negative DC input contact; an AC output connection for outputting an AC phase current of a multi-phase AC output, which is generated by activating the high-side switch and low-side switch on the basis of the DC input; a micro-heat sink that has a coolant intake, a coolant outlet, and a connecting cooling channel structure between the coolant intake and the coolant outlet; wherein the micro-heat sink is designed such that numerous micro-heat sinks, each of which are dedicated to one of numerous switch modules in the inverter, can be releasably connected to one another for fluid exchange at their respective coolant intake and/or coolant outlet.

The present invention provides a reinforcing structure and method for reinforcing valve towers, mainly aiming at valve towers with three or more layers, wherein the four corners of the side face of each layer of a valve section of the valve tower are provided with connecting flanges, and connecting rods are used for connecting the corresponding connecting flanges of adjacent valve towers of the same bridge arm to realize lateral reinforcing. The connection modes of lateral reinforcing mainly include horizontal connection, interleaving connection and cross-layer connection. The invention provides various reinforcing solutions for flexible DC valve towers in the environment of long-term turbulence and strong vibrations, the reinforcing structure is simple and effective, high in reliability and operability, and easy to disassemble, and the stability and safety of the valve towers during transportation and operation are enhanced.

The present invention provides a reinforcing structure and method for reinforcing valve towers, mainly aiming at valve towers with three or more layers, wherein the four corners of the side face of each layer of a valve section of the valve tower are provided with connecting flanges, and connecting rods are used for connecting the corresponding connecting flanges of adjacent valve towers of the same bridge arm to realize lateral reinforcing. The connection modes of lateral reinforcing mainly include horizontal connection, interleaving connection and cross-layer connection. The invention provides various reinforcing solutions for flexible DC valve towers in the environment of long-term turbulence and strong vibrations, the reinforcing structure is simple and effective, high in reliability and operability, and easy to disassemble, and the stability and safety of the valve towers during transportation and operation are enhanced.

A liquid cooling static synchronous series compensator (SSSC) system has inverter valve modules, inverter valve units and liquid cooling blocks. Liquid cooling blocks may be configured to provide a jetted flow, a parallel flow or an individualized flow, within an enclosed fluid chamber, for cooling inverter valve units. Liquid cooling blocks may have voltage isolation.

A power converter includes a semiconductor module, a capacitor module, a control board, and an insulating plate. The capacitor module includes a smoothing capacitor, a first connection terminal electrically connected to the smoothing capacitor and a power supply outside the power converter, and a second connection terminal electrically connected to the semiconductor module. The insulating plate is located between the capacitor module and the control board so as to cover at least one of the first connection terminal and the second connection terminal.

A communication device can be used for communicating between a power equipment controller and power equipment devices of a high-voltage power electronics system. The communication device includes a controller interface communicatively coupled with the power equipment controller, an RF module coupled to the controller interface, and an antenna port coupled to the RF module. A mounting structure is configured to attach the communication device to a valve hall containing the power equipment devices. The mounting structure is permeable for RF signal communication between the communication device and power equipment devices in the valve hall. The mounting structure has a low voltage side to enable placement of the controller interface, the RF module and the antenna port so as to be shielded from disturbances due to high voltages inside the valve hall.