An air cooled resistor arrangement comprising a first elongated tube member which is housed inside a second elongated tube member. The first and second elongated tube members are spaced apart from each other by an air gap for allowing a flow of air to flow through the first elongated tube member and the air gap.

An air cooled resistor arrangement comprising a first elongated tube member which is housed inside a second elongated tube member. The first and second elongated tube members are spaced apart from each other by an air gap for allowing a flow of air to flow through the first elongated tube member and the air gap.

Disclosed are a resistor, a heat dissipater and a combinatory device of the resistor and the heat dissipater, and relates to the field of power electronics. The resistor is cylindrical, and comprises a metal end, an insulating part, a casing, metal bars, a resistor wire, thermally conductive insulating fillers and a metal connection mechanism. The metal connection mechanism of the resistor and the heat dissipater are connected by means of direct contact. The structure and the connection method can shorten the length of the resistor, completely insulate the electrical circuits of the resistor from the possible leakage of the water inlet- and outlet-pipe of the heat dissipater, and enable the combinatory device of the resistor and the heat dissipater to be structurally more compact and the connections thereof cleaner.

A resistor includes a first resistor element. The first resistor element is connected to at least a first electrical terminal and a second electrical terminal. The first resistor element is configured to directly contact cooling media on at least two surfaces of the first resistor element in order to transfer heat away from the first resistor element. The resistor may also include a second resistor element connected to at least the first electrical terminal and the second electrical terminal, where the second resistor element is configured to directly contact the cooling media on at least two surfaces of the second resistor element in order to transfer heat away from the second resistor element.

A resistor includes a first resistor element. The first resistor element is connected to at least a first electrical terminal and a second electrical terminal. The first resistor element is configured to directly contact cooling media on at least two surfaces of the first resistor element in order to transfer heat away from the first resistor element. The resistor may also include a second resistor element connected to at least the first electrical terminal and the second electrical terminal, where the second resistor element is configured to directly contact the cooling media on at least two surfaces of the second resistor element in order to transfer heat away from the second resistor element.

A braking grid cooling system may include a fan having a hub supporting a rotor and at least partially enclosing a stator, and a plurality of fan blades connected to and projecting radially from the hub; and a dynamic braking grid receiving the fan in a nested relation such that a combined height of the grid and the fan is less than a sum of a height of the grid and a height of the fan.

A power diffusing assembly includes a power diffusing body disposed along a flow path of a compressible fluid. The power diffusing body includes passages extending through the power diffusing body and through which at least part of the fluid flows through the power diffusing body. The power diffusing body receives an incoming flow profile of the fluid on an inlet side of the power diffusing body, directs the fluid through the passages in the power diffusing body, and outputs an outgoing flow profile of the fluid out of an outlet side of the power diffusing body. Arrangements of the passages in the power diffusing body are based on the incoming flow profile of the fluid that are received by the power diffusing body and are based on a desired profile of the outgoing flow profile of the fluid exiting out of the power diffusing body.

A power diffusing assembly includes a power diffusing body disposed along a flow path of a compressible fluid. The power diffusing body includes passages extending through the power diffusing body and through which at least part of the fluid flows through the power diffusing body. The power diffusing body receives an incoming flow profile of the fluid on an inlet side of the power diffusing body, directs the fluid through the passages in the power diffusing body, and outputs an outgoing flow profile of the fluid out of an outlet side of the power diffusing body. Arrangements of the passages in the power diffusing body are based on the incoming flow profile of the fluid that are received by the power diffusing body and are based on a desired profile of the outgoing flow profile of the fluid exiting out of the power diffusing body.

A resistive grid includes a frame and at least one resistive element. The frame has a first frame end and a second frame end opposite the first frame end. The first frame end and the second frame end are joined by frame sides. The first frame end has a first length that is shorter than a second length of the second frame end. The at least one resistive element extends between the first frame end and the second frame end. The at least one resistive element has a first portion proximate the first frame end, and a second portion proximate the second frame end. The first portion is configured to have one or both of decreased heat generation or decreased electrical resistance relative to the second portion.

A resistive grid includes a frame and at least one resistive element. The frame has a first frame end and a second frame end opposite the first frame end. The first frame end and the second frame end are joined by frame sides. The first frame end has a first length that is shorter than a second length of the second frame end. The at least one resistive element extends between the first frame end and the second frame end. The at least one resistive element has a first portion proximate the first frame end, and a second portion proximate the second frame end. The first portion is configured to have one or both of decreased heat generation or decreased electrical resistance relative to the second portion.