A fracturing apparatus includes a motor, a first plunger pump, a power supply platform, a gas turbine engine, a generator, and one or more rectifiers. At least two of the gas turbine engine, the generator, and the one or more rectifiers are arranged on the power supply platform. A first end of the generator is connected to the gas turbine engine. A second end of the generator is connected to the one or more rectifiers. The generator is configured to output a voltage to the one or more rectifiers. The one or more rectifiers are configured to provide power to the motor. The motor is configured to drive the first plunger pump

A fracturing apparatus includes a motor, a first plunger pump, a power supply platform, a gas turbine engine, a generator, and one or more rectifiers. At least two of the gas turbine engine, the generator, and the one or more rectifiers are arranged on the power supply platform. A first end of the generator is connected to the gas turbine engine. A second end of the generator is connected to the one or more rectifiers. The generator is configured to output a voltage to the one or more rectifiers. The one or more rectifiers are configured to provide power to the motor. The motor is configured to drive the first plunger pump

The present invention relates to the technical field of heat dissipation of a complete general-purpose machine, comprising: dividing an inner cavity of a housing of a general-purpose machine generator into a low-temperature zone and a high-temperature zone, wherein an end portion of the air deflector is close to a device mounted on the inner wall of the housing, and has a gap for communicating the low-temperature zone and the high-temperature zone with a component mounted on the inner wall of the housing, and guide the air flow to enter from an air inlet of the low-temperature zone of the housing to firstly flow through a heat-generating assembly located in the low-temperature zone, then enter from the gap into the high-temperature zone to flow through the heat-generating assembly located in the high-temperature zone, and then flow out from an air outlet to cool the internal members of the general-purpose machine generator.

The present invention relates to the technical field of heat dissipation of a complete general-purpose machine, comprising: dividing an inner cavity of a housing of a general-purpose machine generator into a low-temperature zone and a high-temperature zone, wherein an end portion of the air deflector is close to a device mounted on the inner wall of the housing, and has a gap for communicating the low-temperature zone and the high-temperature zone with a component mounted on the inner wall of the housing, and guide the air flow to enter from an air inlet of the low-temperature zone of the housing to firstly flow through a heat-generating assembly located in the low-temperature zone, then enter from the gap into the high-temperature zone to flow through the heat-generating assembly located in the high-temperature zone, and then flow out from an air outlet to cool the internal members of the general-purpose machine generator.

In order to obtain an electric rotating machine which can improve rotating machine efficiency by suppressing a harmonic component of rotor magnetomotive force and reducing harmonic core loss, a permanent magnet is furnished in some of inter-magnetic pole portions, the inter-magnetic pole portion being formed between a first claw-shaped magnetic pole portion and a second claw-shaped magnetic pole portion; the shapes of a first chamfered portion and a second chamfered portion, which are provided in the inter-magnetic pole portion where the permanent magnet is inserted, differ from those of a first chamfered portion and a second chamfered portion, which are provided in an inter-magnetic pole portion where the permanent magnet is not inserted; and/or the shapes of a first magnetic flux adjusting portion and a second magnetic flux adjusting portion, which are provided in the inter-magnetic pole portion where the permanent magnet is inserted, differ from those of a first magnetic flux adjusting portion and a second magnetic flux adjusting portion, which are provided in the inter-magnetic pole portion where the permanent magnet is not inserted.

A shoe energy collecting device includes a shell, a piezoelectric assembly, an elastic component, a magnet array, a base, a supporting block, an upper friction assembly and a lower friction assembly. The shell includes a supporting shell and a plastic shell connected in sequence. The base is provided below the supporting block in the supporting shell, the lower friction assembly is provided between the supporting block and the base. The upper friction assembly is provided on an inner wall of a top surface of the plastic shell. A coil is provided on a lower surface of the lower friction assembly at a side of the plastic shell, and the magnet array is provided below the coil. The piezoelectric assembly is provided in the plastic shell, the elastic component is provided on a side wall of the plastic shell away from the supporting block, and connected with the piezoelectric assembly.

A shoe energy collecting device includes a shell, a piezoelectric assembly, an elastic component, a magnet array, a base, a supporting block, an upper friction assembly and a lower friction assembly. The shell includes a supporting shell and a plastic shell connected in sequence. The base is provided below the supporting block in the supporting shell, the lower friction assembly is provided between the supporting block and the base. The upper friction assembly is provided on an inner wall of a top surface of the plastic shell. A coil is provided on a lower surface of the lower friction assembly at a side of the plastic shell, and the magnet array is provided below the coil. The piezoelectric assembly is provided in the plastic shell, the elastic component is provided on a side wall of the plastic shell away from the supporting block, and connected with the piezoelectric assembly.

Aspects of the present disclosure are directed to hybrid energy harvesting systems and methods related thereto. In one example embodiment of the present disclosure, a hybrid energy harvesting unit is disclosed including a guiding structure that provides a constrained trajectory, and one or more coils with a coil length arranged along the guiding structure. Each of the one or more coils encircle a part of the constrained trajectory. The hybrid energy harvesting unit further includes a cantilever structure with an anchoring end and a cantilever tip having a magnetic mass arranged thereon, a piezoelectric element arranged in the cantilever structure and outside the one or more coils, and a permanent magnet partially arranged in the guiding structure and which moves relative to the guiding structure. The anchoring end and the guiding structure is attached to and separated by a distance to the object in motion at a point of contact.

Aspects of the present disclosure are directed to hybrid energy harvesting systems and methods related thereto. In one example embodiment of the present disclosure, a hybrid energy harvesting unit is disclosed including a guiding structure that provides a constrained trajectory, and one or more coils with a coil length arranged along the guiding structure. Each of the one or more coils encircle a part of the constrained trajectory. The hybrid energy harvesting unit further includes a cantilever structure with an anchoring end and a cantilever tip having a magnetic mass arranged thereon, a piezoelectric element arranged in the cantilever structure and outside the one or more coils, and a permanent magnet partially arranged in the guiding structure and which moves relative to the guiding structure. The anchoring end and the guiding structure is attached to and separated by a distance to the object in motion at a point of contact.

A generator assembly for harvesting energy in a bearing arrangement having a first ring and a second ring is provided. The generator assembly includes a plurality of coils attached to the first ring and configured to interact with a magnet ring with alternating magnetization directions attached to the second ring, and a plug connector for supplying power generated by the generator assembly to external devices. The coils are encapsulated and mounted in an outer carrier ring such that the winding axis is oriented in a radial direction of the bearing and the magnet ring is composed of plural permanent magnets attached to an inner carrier ring attached to the inner ring of the bearing.