An exemplary embodiment of the present disclosure relates to a motor-integrated intake apparatus, and the motor-integrated intake apparatus includes: a flow path which is formed in an annular shape in a circular housing; an inlet unit which is installed at one side of the housing and guides a flow of a fluid into the flow path; a discharge unit which is installed at the other side of the housing and guides a discharge of the fluid which is introduced into the inlet unit and passes through the flow path; a piston unit which is made of a magnetic material and compresses the fluid, which is introduced through the inlet unit, while rotating along the flow path; and a coil unit which is installed on the housing and provides rotational power to the piston unit by forming a magnetic field.

The present invention provides a high-speed motor for supplying high-output power by preparing a power transmission device, which increases rotational power at the front of a motor converting electrical energy into mechanical energy, so as to cause a rotary motion, obtain power, and supply the power, such that the power transmission device generates torque through an interaction of attraction and repulsion between a rotating magnetic field and a magnetic field generated by receiving the rotational power of the electric motor of receiving the rotational power of the electric motor and external electric power, thereby implementing a motor for transferring power with an increased number of revolutions and torque.

The present invention provides a high-speed motor for supplying high-output power by preparing a power transmission device, which increases rotational power at the front of a motor converting electrical energy into mechanical energy, so as to cause a rotary motion, obtain power, and supply the power, such that the power transmission device generates torque through an interaction of attraction and repulsion between a rotating magnetic field and a magnetic field generated by receiving the rotational power of the electric motor of receiving the rotational power of the electric motor and external electric power, thereby implementing a motor for transferring power with an increased number of revolutions and torque.

Disclosed is a new classification of Turbine Prime Mover, capable of producing high magnitudes of rotational speed, potential rotating energy and power production. The invention is a rotating machine adapted to be propelled by the net force created by asymmetric radio frequency resonant cavities (7). The turbine employs thrusters (7) electrically driven by microwave signals produced from adapted Klystron Tubes (3). By optimizing microwave production, and thruster pressures via the internal radio frequency cavity resonance, power in the field of the thruster by wave tube amplification, internal reflectivity and cooling, the principles of rotor-dynamics are applied to produce a new class of energy storage machine. Low power inputs yield high energy magnitudes over time accumulated thruster operation in the rotor. The turbine rotor is capable of acting as a prime mover for energy injection into a rotor mass, or can create real work by outputting rotational energy into torque.

Disclosed is a new classification of Turbine Prime Mover, capable of producing high magnitudes of rotational speed, potential rotating energy and power production. The invention is a rotating machine adapted to be propelled by the net force created by asymmetric radio frequency resonant cavities (7). The turbine employs thrusters (7) electrically driven by microwave signals produced from adapted Klystron Tubes (3). By optimizing microwave production, and thruster pressures via the internal radio frequency cavity resonance, power in the field of the thruster by wave tube amplification, internal reflectivity and cooling, the principles of rotor-dynamics are applied to produce a new class of energy storage machine. Low power inputs yield high energy magnitudes over time accumulated thruster operation in the rotor. The turbine rotor is capable of acting as a prime mover for energy injection into a rotor mass, or can create real work by outputting rotational energy into torque.

Wireless power transmission (WPT) systems are provided. For example, the WPT system can use one or more power transmitting coils and a receiver for electromagnetically coupled wireless power transfer. The electrodynamic receiver can be in the form of an electrodynamic transducer where a magnet is allowed to oscillate near a receiving coil to induce a voltage in the receiving coil, a piezoelectric transducer where the magnet causes a vibrating structure with a piezoelectric layer to move, an electrostatic transducer where movement of the magnet causes a capacitor plate to move, or a combination thereof. An alternating magnetic field from the transmitting coil(s) excites the magnet in the receiver into mechanical resonance. The vibrating magnet then functions similar to an energy harvester to induce voltage/current on an internal coil, piezoelectric material, or variable capacitor. Embodiments utilize magnetic coupling and electromechanical resonance for safe, spatially distributed, low-frequency power delivery to portable devices.

The present invention is a permanent magnet external-rotating brushless motor and an induction motor. It is multi-stabilized in order to fully utilize the characteristics of a magnetic field of 360 degrees, and is multi-functionalized by a wire group selection switch, and multi-stator multi-function The different stator-to-stator line sets are connected to the output power generation or the power supply drive to select different combinations of functions, such as a programmable logic controller module or a 32-bit 32-channel multi-channel servo steering control module, and the execution of the array module is written. The modes are grouped into action groups, and then the computer is used to assist the driver in making decisions by analyzing the artificial road and the road type with artificial intelligence decision trees.

This present invention provides a novel DC dynamo which is characterized by making the magnetic lines of flux pass through an air gap between the rotator and the stator in the same direction, thus the most of armature coils can always receive the electromotive force of the same polarity in the same direction. Therefore, bidirectional energy conversion between the mechanical energy and the electrical energy of the armature coils in series can still proceed in the absence of commutators and induced the armature to generate sufficient electromotive force to conveniently regulate suitable terminal voltages and the ratios of the rotating speed and the moving speed thereof.

A stator or a rotor for use in an electrical machine comprises a composite element having a rigid mass suitable for including at least one magnetostrictive electrode bar, at least one magnetostrictive electrode bar, and a piezoelectric material in between the rigid mass material and the magnetostrictive electrode bars. The rigid mass, the magnetostrictive electrode bars and the piezoelectric material are arranged such that applying a voltage between the rigid mass and one or more magnetostrictive electrodes, causes piezoelectric effects in the piezoelectric material inducing stress in the bi-axial plane of the at least one magnetostrictive bar and an altered permeability of the at least one magnetostrictive bar in a direction perpendicular to the bi-axial stress plane.

A DC machine for connection to an electrical system may include a stator configured as a portion of the DC machine; a rotor configured as a portion of the DC machine being rotatable with respect to the stator; and a control circuit to control the rotor to allow the rotor to continuously slip with respect to the stator.