RU2818077C1 - Electric machine with transverse magnetic flux - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, namely to magnetoelectric machines with transverse magnetic flux. Electric machine is characterized by the fact that geometrical dimensions of magnets width b_m and pole pitch of rotor τ for electric machine design with axial air gap are selected so that the ratio of the width of the magnets to the pole pitch of the rotor is equal to 0.4 (b_m/τ=0.4). Stator is located on one side of the rotor. Rotor includes two sets of flux concentrators alternating with magnets and placed along the rotor radius, and the stator is located on one side of the rotor and has two oppositely connected windings and two sets of teeth. Total number of stator teeth is equal to the number of poles of the machine.

EFFECT: increasing power factor of electric machine with transverse flow, reducing rated current and losses in copper of winding, increasing efficiency and torque of the machine.

2 cl, 2 dwg

Description

The invention relates to the field of electrical engineering and power engineering, namely to synchronous electric machines with excitation from permanent magnets and transverse magnetic flux. The main area of application of the invention: a source of energy for supplying consumers of wind power plants (direct drive of a wind turbine with variable rotation speed), as well as a traction electric drive (wheel motor).

The essence of the technical problem solved by the claimed invention is as follows.

The subject of the study is a cross-flux magnetoelectric machine, which includes a stator containing horseshoe-shaped ferromagnetic cores oriented so that the magnetic flux that circulates within these cores is directed substantially perpendicular to the rotor's axis of rotation. The main difference between an electric machine with a transverse magnetic flux and a machine with a longitudinal flux (radial, tangential and axial) is that in the structure of this machine the electric and magnetic circuits are not connected, but are separated, which allows increasing the space for windings without reducing the available space for main magnetic flux and make a machine with very small pole division compared to other machines. The perpendicular orientation of the magnetic flux in the stator cores relative to the direction of rotation gives cross-flux electric machines a high ratio of mechanical torque per unit weight of the electric machine. In addition, in a cross-flow machine, the low active mass to torque ratio is due to the winding design, which has virtually no inactive parts.

However, the cross flux machine has disadvantages such as complex design, production difficulties due to the large number of individual parts (cores and magnets) and special manufacturing and assembly methods, as well as low power factor, large flux leakage fluxes and high tooth torque value .

Permanent magnet-excited cross-flow machines are known. Their designs differ in the direction of flux along the radial or axial air gap, the shape of the core (U-shaped, Conforming, E-shaped and Z-shaped), internal or external rotor topology, active or passive stator design, arrangement of permanent magnets, single-turn or double-turn phase winding , double or single stator design, etc. Typically, most designs use ferromagnetic shunts to reduce leakage fluxes, see patent EP 3080895, patent US 8053944, in which the machine is configured with a stator generally aligned with the plane of rotation of the rotor (axial clearance configuration), or the machine is configured with a stator , rotated 90 degrees with respect to the plane of rotation of the rotor (radial clearance configuration). Permanent magnets can be made with "surface" magnetization or with concentrated flux. In the first version, permanent magnets are magnetized in a direction perpendicular to the direction of rotation, in the second, permanent magnets have a magnetization direction parallel to rotation. The concentrated flow option allows for greater torque density.

US Pat. No. 9,559,558 presents an embodiment of a 3-phase cross-flow electrical machine that includes a plurality of phase modules adapted to be axially mounted together with a plurality of fastening elements. The phase modules are substantially identical and interchangeable and include rotor blocks and stator blocks, each of which is formed as a complete ring and has an associated winding. The stator winding consists of two separate (ordinary) ring coils, the currents in which are in opposite directions. Each pair of axially adjacent phase modules is adapted to be angularly positioned relative to each other to define a phase shift, typically set to approximately 120° between adjacent phase modules to provide three-phase symmetrical electrical current. Other solutions have been proposed, for example, patents WO 2011033106 and EP 2317633.

The original traditional cross-flux machine design has a rotor with permanent magnets of alternating polarity attached to bars of magnetic material that serve as magnetic return conductors. The stator consists of U-shaped stator elements made of magnetic material, the amount of which is equal to half the amount of magnets. The stator winding is made in the form of a ring winding. US Pat. No. 5,117,142 has already proposed a new design that has twice as many stator elements within the same volume as the traditional one and therefore the power density per unit volume is doubled for the same amount of permanent magnet material. The second design has a higher efficiency, since the copper losses of the designs are the same. The alternating stator elements have the same shape, asymmetrical relative to the magnetization axis of the permanent magnet, and when alternating, but alternately, they rotate 180° relative to the axis of the permanent magnet. The disadvantage of the design is the increase in the axial size of the machine.

However, a design with a disk rotor with permanent magnets located between a double-sided stator with identical symmetrical elements has become more widespread, for example, patents US 11296585; US 20210075276. Detailed research can be found in the article by T. Husain, I. Hasan, and Y. Sozer. Design Considerations of a Transverse Flux Machine for Direct-Drive Wind Turbine Applications. ConferencePaper NREL/CP-5D00-66391, January 20.

The disadvantages of using a double-sided stator include, first of all, the doubling of the axial overall size of the machine, as well as the volume of permanent magnets.

In the article by A.M. Ajamloo, R. Nasiri-Zarandi, A. Ghaheri.Design and Optimization of a New TFPM Generator with Improved Torque Profile.The 34th InternationalPowerSystemConference (PSC2019) 9-11 December, NirooResearchlnstitute, Tehran, 1 haprotor is flux concentrated and has an annular permanent magnet , parts of the stator are of an identical configuration, but face in the axial direction relative to neighboring parts, the armature has two windings in which EMF is induced from the fluxes of even and odd poles and which are connected counter-currently.

An electric machine with transverse flux is known according to RF patent 2797363, containing a stator, a coil and a rotor, which interacts with the stator as a switching device, as well as a set of flux concentrators alternating with magnets, characterized by the fact that the geometric dimensions of the width of the magnets b _m and the pole division of the rotor τ for the design of an electric machine, both with axial and radial air gaps, are selected in such a way that the ratio of the width of the magnets to the rotor pole pitch is 0.4 (b _m /τ = 0.4). This electrical machine can be made in the form of a multiphase device. The stator of this electrical machine can be located inside the rotor.

This technical solution, as the closest to the stated technical essence and the achieved result, was adopted as its prototype.

This electric machine makes it possible to significantly increase the power factor of a cross-flow electric machine, which, in turn, makes it possible to reduce the rated current and losses in the copper windings, and increase the efficiency and torque of the machine.

At the same time, the disadvantages of the prototype are that with a double-sided arrangement of the stator, the main disadvantage of such electrical machines remains, which is the increase in the axial dimensions of the machine. At the same time, magnetoelectric synchronous machines with transverse flow are made with a small pole pitch and a large number of poles, which determines a relatively large diameter. Consequently, the restrictions in the radial direction are much less than in the axial direction.

The objective of the claimed invention is to create an electric machine with a transverse magnetic flux, which has an increased power factor and has a minimum volume by reducing the axial size.

The essence of the claimed technical solution is expressed in the following set of essential features, sufficient to solve the technical problem specified by the applicant and obtain the technical result provided by the invention.

According to the invention, an electric machine with a transverse magnetic flux, containing a stator, a coil and a rotor that interacts with the stator as a switching device, as well as a set of flux concentrators alternating with magnets, while the geometric dimensions of the magnet width b _m and the rotor pole division τ for the electrical design machines with an axial air gap are selected in such a way that the ratio of the width of the magnets to the pole pitch of the rotor is equal to 0.4 (b _m /τ = 0.4), characterized in that the rotor includes two sets of flux concentrators, alternating with magnets and placed along the radius of the rotor, and the stator is located on one side of the rotor and has two counter-connected windings and two sets of teeth, and the total number of stator teeth is equal to the number of poles of the machine.

In addition, the claimed technical solution is characterized by the presence of an additional optional feature, namely:

- the electric machine can be made in the form of a multiphase device.

The set of essential features of an electric machine that we have declared ensures the achievement of a technical result, namely that the rotor includes two sets of flux concentrators, alternating with magnets and located along the radius of the rotor, and the stator is located on one side of the rotor and has two counter-connected windings and two a set of teeth, and the total number of stator teeth is equal to the number of poles of the machine, unattainable using any known analogue and not obvious to a specialist in this field of technology.

The essence of the proposed technical solution is illustrated by a drawing, in which figure 1 shows various configurations of stator magnetic cores with a double-sided stator arrangement: a - according to US patent 5117142, b - according to US patent 11296585, c - according to the article by A. M. Ajamlo, in fig. 2 - configuration of the magnetic cores of the claimed electric machine with a one-sided stator arrangement with an equal number of poles and stator teeth: a - axial projection, b - radial projection.

In fig. 1 and fig. 2 positions indicate: 1 - permanent magnets, 2 - rotor magnetic circuit, 3 - stator magnetic circuit, 4a and 4b - windings; The arrows indicate the magnetic flux paths.

The rotor of the claimed electric machine includes two sets of flux concentrators, alternating with magnets and located along the radius of the rotor. The stator is located on one side of the rotor and has two sets of teeth. The odd stator teeth are connected to an outer set of rotor flux concentrators, and the even stator teeth are connected to an inner set of rotor flux concentrators, the total number of stator teeth being equal to the number of machine poles. The even and odd sets of stator teeth have their own winding. Since the flux linkage distribution is a four function, the Fourier series contains only cosines; each member of the series is a periodic function with a period of 2π. The even and odd sets of stator teeth are shifted relative to each other by an amount k, so the two windings are connected back to back.

The claimed electric machine with transverse magnetic flux is designed in such a way that the magnetic flux is perpendicular to the direction of rotation of the rotor and is created by two sets of flux concentrators alternating with magnets and placed along the radius of the rotor. Through the air gap, the magnetic flux hits two sets of stator teeth located on one side of the rotor and induces an emf in the ring winding of each set. The total number of stator teeth is equal to the number of machine poles. The sets of stator teeth are shifted relative to each other by an amount π, so their windings are connected counter-currently. When connecting the windings, it is taken into account that the sets of stator teeth are located at different design diameters. If the condition is met, the ratio of the width of the magnets to the pole pitch of the rotor is 0.4 (b _m /τ = 0.4); at a smaller diameter, the width of the magnet will be smaller and the magnetic flux will be lower. To obtain the same EMF in the windings, for a winding located on a smaller diameter, the number of turns must be increased accordingly. Calculations show that this condition is feasible and the windings have almost identical external characteristics.

The possibility of industrial application of the claimed technical solution is confirmed by the means and methods known and described in the application, with the help of which it is possible to implement the invention in the form as it is characterized in the claims.

Claims (2)

1. An electric machine with a transverse magnetic flux, containing a stator, a coil and a rotor that interacts with the stator as a switching device, as well as a set of flux concentrators alternating with magnets, while the geometric dimensions of the magnet width b _m and the rotor pole division τ for the electrical design machines with an axial air gap are selected in such a way that the ratio of the width of the magnets to the pole pitch of the rotor is 0.4 (b _m /τ = 0.4), characterized in that the rotor includes two sets of flux concentrators alternating with magnets and placed along the radius of the rotor, and the stator is located on one side of the rotor and has two counter-connected windings and two sets of teeth, and the total number of stator teeth is equal to the number of poles of the machine. 2. Electric machine according to claim 1, characterized in that it is made in the form of a multiphase device.