A transformer including a transformer tank, an expansion tank, and piping connecting the tanks enabling liquid to flow there between. The piping includes a valve configured for liquid to flow from the transformer to the expansion tank when the pressure is above a predefined first threshold and for preventing the liquid to flow from the transformer to the expansion tank when the pressure is below the first threshold. The valve is also configured for liquid to flow from the expansion to the transformer tank when the pressure is below a predefined second threshold and for preventing the liquid to flow from the expansion to the transformer tank when the pressure is above the predefined second threshold.

A rupture resistant system, including a tank configured to increase an inner volume of the tank under increased pressure conditions, wherein the tank, a sidewall extending about the inner volume of the tank, and wherein the sidewall includes an interior surface and an exterior surface, a bottom wall coupled to the sidewall, and a tank cover coupled to the sidewall opposite the bottom wall, wherein the tank cover includes a first plate coupled to a second plate, wherein the second plate extends from the first plate, and the first plate couples to a second end of the sidewall with a joint without overlapping the interior and exterior surfaces of the sidewall. The system also includes a radiator coupled to the tank, the radiator comprising a first panel and a second panel positioned at a distance from the first panel, the first panel and second panel being configured to increase the distance of the inner volume of the radiator.

A rupture resistant system, including a tank configured to increase an inner volume of the tank under increased pressure conditions, wherein the tank, a sidewall extending about the inner volume of the tank, and wherein the sidewall includes an interior surface and an exterior surface, a bottom wall coupled to the sidewall, and a tank cover coupled to the sidewall opposite the bottom wall, wherein the tank cover includes a first plate coupled to a second plate, wherein the second plate extends from the first plate, and the first plate couples to a second end of the sidewall with a joint without overlapping the interior and exterior surfaces of the sidewall. The system also includes a radiator coupled to the tank, the radiator comprising a first panel and a second panel positioned at a distance from the first panel, the first panel and second panel being configured to increase the distance of the inner volume of the radiator.

An oil filled electrical equipment includes an assembly for oil filling and hermetically sealing the electrical equipment. The assembly includes a cylindrical bellow mounted on a plate of the electrical equipment with one or more fittings. The bellow provides pressure and volume compensation in the electrical equipment. The bellow includes a cylinder with a plurality of convolutions for expanding and contracting to provide the compensation. The bellow further includes two covers attached with the cylinder at two ends of the cylinder. Each cover includes a cylindrical part that is open at a first end and closed at a second end. The first end terminates at a circular face for mounting the cover on a convolution at a corresponding end of the cylinder. The second end includes an opening for oil filling and hermetically sealing the electrical equipment, and mounting the bellow on the plate.

An oil filled electrical equipment includes an assembly for oil filling and hermetically sealing the electrical equipment. The assembly includes a cylindrical bellow mounted on a plate of the electrical equipment with one or more fittings. The bellow provides pressure and volume compensation in the electrical equipment. The bellow includes a cylinder with a plurality of convolutions for expanding and contracting to provide the compensation. The bellow further includes two covers attached with the cylinder at two ends of the cylinder. Each cover includes a cylindrical part that is open at a first end and closed at a second end. The first end terminates at a circular face for mounting the cover on a convolution at a corresponding end of the cylinder. The second end includes an opening for oil filling and hermetically sealing the electrical equipment, and mounting the bellow on the plate.

An intelligent air-drying system and method are provided. The intelligent air-drying system includes an air-drying device and an application program. The air-drying device includes a device body, a sensing unit, a heater, and a processing unit. The device body has a water-absorbing material for absorbing moisture in the air. The sensing unit is disposed on the device body to detect the humidity of the environment where the air-drying device is located. The heater is disposed on the device body to heat the water-absorbing material. The processing unit is coupled to the sensing unit and the heater, and the processing unit executes the application program. The startup timing of the heater is dynamically predicted based on the daily humidity change measured by the sensing unit, and the heater is started before the water-absorbing material reaches saturation to ensure the water-absorbing and dehumidifying capabilities of the water-absorbing material.

A transformer having a transformer core that forms a magnetic flux path between and through a top yoke, leg, and bottom yoke of the transformer core. A winding can be disposed about the leg. Further, a flitch plate, which can have at least one slot that is configured to reduce eddy losses generated by the winding, can be disposed adjacent to the leg and extend between the top yoke and the bottom yoke. The flitch plate can be clamped to the top and bottom yokes by top and bottom clamps, respectively. The top and bottom clamps can each include at least one cutout that reduces an attraction of stray flux from the winding and into the corresponding top and bottom clamps. Additionally, at least one of the top clamp and the bottom clamp can include an internal lattice structure.

A transformer having a transformer core that forms a magnetic flux path between and through a top yoke, leg, and bottom yoke of the transformer core. A winding can be disposed about the leg. Further, a flitch plate, which can have at least one slot that is configured to reduce eddy losses generated by the winding, can be disposed adjacent to the leg and extend between the top yoke and the bottom yoke. The flitch plate can be clamped to the top and bottom yokes by top and bottom clamps, respectively. The top and bottom clamps can each include at least one cutout that reduces an attraction of stray flux from the winding and into the corresponding top and bottom clamps. Additionally, at least one of the top clamp and the bottom clamp can include an internal lattice structure.

A sensor system includes a sensor network comprising at least one optical fiber having one or more optical sensors. At least one of the optical sensors is arranged to sense vibration of an electrical device and to produce a time variation in light output in response to the vibration. A detector generates an electrical time domain signal in response to the time variation in light output. An analyzer acquires a snapshot frequency component signal which comprises one or more time varying signals of frequency components of the time domain signal over a data acquisition time period. The analyzer detects a condition of the electrical device based on the snapshot frequency component signal.

A sensor system includes a sensor network comprising at least one optical fiber having one or more optical sensors. At least one of the optical sensors is arranged to sense vibration of an electrical device and to produce a time variation in light output in response to the vibration. A detector generates an electrical time domain signal in response to the time variation in light output. An analyzer acquires a snapshot frequency component signal which comprises one or more time varying signals of frequency components of the time domain signal over a data acquisition time period. The analyzer detects a condition of the electrical device based on the snapshot frequency component signal.