Provided are a power generation apparatus and an aquarium equipment. The power generation apparatus includes a water pump and a magnetic induction generator. The water pump includes a housing, a stator mounted in the housing, a first rotor assembly, and an impeller connected to the first rotor assembly. The first rotor assembly includes a first permanent magnet rotor and a first rotating shaft disposed at an axis of the first permanent magnet rotor. The first permanent magnet rotor is disposed adjacent to the stator. The magnetic induction generator is disposed adjacent to the stator or to the first permanent magnet rotor and is operative to be coupled to an electric device. The stator includes a coil winding operative to be coupled to an external power source, so that when the coil winding is coupled to an input alternating current, the first permanent magnet rotor rotates enabling the magnetic induction generator to generate an induced current to power up the electric device. The aquarium equipment includes the power generation apparatus described above.

Disclosed are a water pump and an aquarium equipment that includes the water pump. The water pump includes a stator, a rotor assembly, an impeller, and a power generation induction module. The stator includes a U-shaped iron core and a coil winding wound around the U-shaped iron core. The coil winding is connected to an external power source. The rotor assembly includes a rotating shaft and a permanent magnet rotor. The impeller is connected to the rotating shaft or to the permanent magnet rotor. The power generation induction module is spaced apart from the rotor assembly. The rotor assembly and the power generation induction module are both disposed within a range of a magnetic field at an opening of the U-shaped iron core. The power generation induction module is electrically connected to an electric equipment.

Provided are a power generation apparatus and an aquarium equipment including the power generation apparatus. The power generation apparatus includes a water pump and a power generation induction coil. The water pump includes a stator, a rotor assembly, and an impeller. The rotor assembly is coupled to the impeller, the stator includes a U-shaped iron core and a coil winding wound around the U-shaped iron core. The coil winding is operative to be coupled to an external power source. The rotor assembly includes a rotating shaft and a permanent magnet rotor coupled to the rotating shaft. The power generation induction coil is wound around an exterior of the permanent magnet rotor and coupled to an electric device. The permanent magnet rotor is disposed at an open end of the U-shaped iron core. When the coil winding is energized, the permanent magnet rotor rotates relative to the power generation induction coil enabling the power generation induction coil to generate an induced current to power up the electric device.

Provided are a power generation apparatus and an aquarium equipment including the power generation apparatus. The power generation apparatus includes a water pump and a power generation induction coil. The water pump includes a stator, a rotor assembly, and an impeller. The rotor assembly is coupled to the impeller, the stator includes a U-shaped iron core and a coil winding wound around the U-shaped iron core. The coil winding is operative to be coupled to an external power source. The rotor assembly includes a rotating shaft and a permanent magnet rotor coupled to the rotating shaft. The power generation induction coil is wound around an exterior of the permanent magnet rotor and coupled to an electric device. The permanent magnet rotor is disposed at an open end of the U-shaped iron core. When the coil winding is energized, the permanent magnet rotor rotates relative to the power generation induction coil enabling the power generation induction coil to generate an induced current to power up the electric device.

A motor-generator includes a stator disposed along a centerline including a stator pole, a first stator winding and a second stator winding, wherein the first stator winding is wound on the stator pole and the second stator winding is wound on the stator pole, and at least one rotor axially disposed from the stator along the centerline.

A motor-generator includes a stator disposed along a centerline including a stator pole, a first stator winding and a second stator winding, wherein the first stator winding is wound on the stator pole and the second stator winding is wound on the stator pole, and at least one rotor axially disposed from the stator along the centerline.

A high-efficient magnetic rotating apparatus and motor generator are provided which are capable of further reducing a detent torque. The magnetic rotating apparatus and the motor generator each includes a stator in which cores with a winding are disposed and a rotor in which permanent magnets are disposed. The permanent magnet has a magnetic pole of an N-pole or an S-pole and has a counter face, opposed to the core, with an inclination angle. In each set of magnet bodies, the two permanent magnets are so disposed that two counter faces have different magnetic poles and are inclined reversely. The two permanent magnets are magnetically connected through a joint member made of a magnetic material so that the two counter faces act as magnetic poles on both ends of the magnet body.

A high-efficient magnetic rotating apparatus and motor generator are provided which are capable of further reducing a detent torque. The magnetic rotating apparatus and the motor generator each includes a stator in which cores with a winding are disposed and a rotor in which permanent magnets are disposed. The permanent magnet has a magnetic pole of an N-pole or an S-pole and has a counter face, opposed to the core, with an inclination angle. In each set of magnet bodies, the two permanent magnets are so disposed that two counter faces have different magnetic poles and are inclined reversely. The two permanent magnets are magnetically connected through a joint member made of a magnetic material so that the two counter faces act as magnetic poles on both ends of the magnet body.

A converter includes: a terminal that receives code-modulated power into which first alternating-current power has been code-modulated with a modulation code; and a circuit that converts the code-modulated power with a conversion code to generate second alternating-current power. The conversion code is based on the modulation code. A frequency of the second alternating-current power is higher than a frequency of the first alternating-current power.

A motor with self power generation includes a motor body, at least one magnetic element, a shield case, an induction element, a transfer circuit board and a working module. The motor body includes a shaft member. The at least one magnetic element, located at the shaft member, is to generate a dynamic electromagnetic induction space while the shaft member rotates. The shield case, located close to the shaft member, is to shield the shaft member. The induction element, fixed at the shield case, has a portion located inside the dynamic electromagnetic induction space to generate an induction power while the shaft member rotates. The transfer circuit board has a transfer circuit electrically coupled with the induction element to receive the induction power to further generate a working power. The working module, electrically coupled with the transfer circuit, is to receive the working power to execute a default work.