An object of the invention is to provide an electroporation method for treating vesicles with exogenous material for insertion of the exogenous material into the vesicles which includes the steps of: a. retaining a suspension of the vesicles and the exogenous material in a treatment volume in a chamber which includes electrodes, wherein the chamber has a geometric factor (cm.sup.−1) defined by the quotient of the electrode gap squared (cm.sup.2) divided by the chamber volume (cm.sup.3), wherein the geometric factor is less than or equal to 0.1 cm.sup.−1, wherein the suspension of the vesicles and the exogenous material is in a medium which is adjusted such that the medium has conductivity in a range spanning 50 microSiemens/cm to 500 microSiemens/cm, wherein the suspension is enclosed in the chamber during treatment, and b. treating the suspension enclosed in the chamber with one or more pulsed electric fields. With the method, the treatment volume of the suspension is scalable, and the time of treatment of the vesicles in the chamber is substantially uniform.

The invention involves a switched reluctance motor, comprising a stator and a rotor rotatable relative to the stator. The stator comprises several circumferentially arranged coils and stator poles, the stator poles forming the cores of the coils. The rotor comprises several counter poles for interacting with the stator poles for applying a reluctance torque on the rotor. The motor comprises phase inputs for receiving an actuation signal for actuating one or more phase stages. Each stator coil is associated with a phase stage, such that each phase stage comprises at least two coils. Each phase stage comprises a circuit stage including a switching arrangement comprising switches for selectively switching the coils of said phase stage in either one of a parallel, a serial, or a parallel-serial electrical configuration.

An electric motor may comprise a rotor and a stator comprising rotor and stator teeth, respectively. A non-uniform angular spacing or grouping of rotor teeth may facilitate desired rotational speeds of the rotor.

A stator assembly has coils in a distributed winding configuration. A poly-phase switched reluctance motor assembly may include a stator assembly with multiple coils in a distributed winding configuration. The stator assembly may have a central bore into which a rotor assembly having multiple poles is received and configured to rotate. A method of controlling a switched reluctance motor may include at least three phases wherein during each conduction period a first phase is energized with negative direction current, a second phase is energized with positive current and there is at least one non-energized phase. During each commutation period either the first phase or second phase switches off to a non-energized state and one of the non-energized phases switches on to an energized state with the same direction current as the first or second phase that was switched off. The switched reluctance motor may include a distributed winding configuration.

The invention relates to an energy and power generation system and process, especially self-powered motor and generator/alternator set-up. The system has at least one upsized drive shaft adapted as one of the main elements thereof including an upsized main body of non-typical size having substantially and proportionately enlarged diameter and/or length based on typical standard drive shaft sizes normally and correspondingly adapted for power generation systems or devices of commensurate capacity ratings, preferably motor-generator systems, generators or alternators, or electric motors. When in inertial rotation, the upsized shaft inertially produces/generates and adds input power/energy to the subsequent electrical input power/energy derived from the motor resulting in an overall input power/energy that is efficiently converted/transformed by the generator/alternator into electrical output power/energy that is greater than the electrical input power/energy supplied to the motor. The excess useful electrical output power/energy is used for other loads and/or charging/recharging a power source or battery pack that is used to initially start up the motor.

A coil winding for an electric motor, and systems, components, assemblies, and methods thereof, can comprise turns of a predetermined number of electrically conductive wires on a first side of the coil winding twisted together in a clockwise direction; and turns of the predetermined number of the electrically conductive wires on a second side of the coil winding opposite the first side twisted together in a counterclockwise direction.

A process for assembling a rotor of a variable-reluctance synchronous motor, characterised in that it comprises the steps of: i. preparing a plurality of discs having a through-cavity for each polar sector for housing at least a magnet; ii. positioning the discs in sequence along an axis of rotation for forming the rotor, so that the through-cavities are aligned to one another; iii. preparing magnets having an identical depth that is smaller than the depth of the rotor, and a frontal section that is identical to or smaller than the area of the cavity; iv. calculating the number of magnets to be inserted, for each polar sector, in a sequence so as to occupy only part of the total depth of the rotor as a function of the performances to be obtained; v. inserting the calculated number of magnets in a series of cavities aligned for each polar sector. The invention also relates to a rotor of a variable-reluctance synchronous motor assembled using the process set out above.

The invention predominantly relates to a rotating electrical machine for a motor vehicle, comprising: a rotor having an even number of pole pairs Np; and a stator (10) comprising a body provided with slots and a three-phase winding (14) inserted into the slots in the stator body. The three-phase winding (14) comprises: at least a first group (G1) of portions of phases (U, V, W) and a second group (G2) of portions of phases (U, V, W) which are associated with a first set of at least three bridge arms (21.1); and at least a third group (G3) of portions of phases (U, V, W) and a fourth group (G4) of portions of phases (U, V, W) which are associated with a second set of at least three bridge arms (21.1).

The invention predominantly relates to a rotating electrical machine for a motor vehicle, comprising: a rotor having an even number of pole pairs Np; and a stator (10) comprising a body provided with slots and a three-phase winding (14) inserted into the slots in the stator body. The three-phase winding (14) comprises: at least a first group (G1) of portions of phases (U, V, W) and a second group (G2) of portions of phases (U, V, W) which are associated with a first set of at least three bridge arms (21.1); and at least a third group (G3) of portions of phases (U, V, W) and a fourth group (G4) of portions of phases (U, V, W) which are associated with a second set of at least three bridge arms (21.1).

The present invention aims to improve conductivity of a conductive member on a first axial side, the conductive member being inserted into a flux barrier. An aspect of a synchronous reluctance motor includes flux barriers provided at respective poles of a rotor core, and conductive members that are branched from a first axial side, which is one side in an axial direction, and that are positioned in the flux barriers different from one another.