RU128415U1 - SYNCHRONOUS ELECTRIC GENERATOR - Google Patents

Abstract

1. A synchronous electric generator containing a windingless rotor, a stator formed by three windings mounted coaxially with the shaft and an even number equal to 2p, uniformly spaced around the circumference of the U-shaped ferromagnetic staples, the middle and one of the side stator windings covered by one group of p located through one ferromagnetic staples, the middle and other lateral stator windings are covered by another group of p ferromagnetic staples, and these groups of staples are shifted along the axis by at least the width of the stator winding, characterized in that the U-shaped brackets are oriented at their ends along the machine axis and the brackets of one group are directed in the opposite direction relative to the brackets of the other, and the rotor is made in the form of two end magnetic systems located on different sides of the stator, each of which is formed by p ferromagnetic elements, also having the shape of U-shaped staples uniformly spaced around the circle with a step equal to the staples of the stator groups, and forming closed magnetic circuits with them, having in the longitudinal section of the generator a holistic a twisted magnetic circuit, divided into two parts by an air gap, and the U-shaped ferromagnetic brackets of one end magnetic system of the rotor are located opposite the ferromagnetic brackets of its other end magnetic system. 2. The synchronous electric generator according to claim 1, characterized in that the end magnetic systems are mounted with a 1/3 tooth division of the stator relative to each other, their ferromagnetic elements are completely or partially made of hard magnetic material and are installed after magnetizing them in such a way

Description

The utility model relates to the field of electromechanics, namely to contactless synchronous generators and can be used in low and medium power supply systems.

Known contactless synchronous generators with a windingless rotor made of separate uniformly distributed around the circumference of the ferromagnetic staples of a U-shaped stator and concentrated stationary excitation windings and anchors covered by rods [Non-contact electric machines. - Riga: Zinatne, issue IX, 1970, p.25.].

In these generators, the possibility of their use is practically excluded, due to the presence of a significant variable component of the EMF in the field winding and due to its presence an unacceptable level of pulsation of the flux linkage of the armature windings, a pronounced non-sinusoidality of the shape of the voltage curve.

The disadvantage of these electric machines is also that they have significant losses in the windings and the magnetic circuit and are suitable only for generating single-phase alternating current electricity.

The closest in technical essence to the proposed utility model is a synchronous generator described in US patent No. 3, 588, 559, IPC Н02К 17/42, publ. 1971]. This generator contains a windingless rotor, a stator formed by three windings installed coaxially with the shaft and an even number (equal to 2p) of U-shaped ferromagnetic staples evenly spaced around the circumference, the middle and one of the side stator windings being covered by one group of "p" located through one ferromagnetic staples, the middle and other lateral stator windings are covered by another group of “p” ferromagnetic staples and these groups of staples are shifted along the axis by at least the width of the stator winding.

The disadvantages of the generator are significant losses in the rotor steel from eddy currents even when it is charged, due to the closure of these currents along, rather than across the sheets, and the complicated technology of manufacturing the stator and rotor magnetic cores, which is characterized by the presence of waste, associated with the irrational use of steel. In addition, the scope of the generator is limited to single-phase alternating current generation systems.

The technical task of the utility model is to reduce losses from eddy currents and waste-free technology for manufacturing the rotor and stator magnetic circuits.

The technical result of a synchronous electric generator is that its magnetic system has wider functional capabilities due to its ability to generate a three-phase alternating current without complicating the design, which is achieved by the fact that in the known synchronous electric generator containing a windingless rotor, three stator coaxially mounted with the shaft windings and 2p U-shaped ferromagnetic staples evenly spaced around the circumference, with the middle and one of the side stator windings of the ohm of one group of “p” ferromagnetic staples located through one, the middle and other lateral stator windings are covered by another group of “p” ferromagnetic staples and these groups of staples are shifted along the axis by at least the width of the stator winding, U-shaped staples are oriented with their ends oriented along the axis of the machine and the brackets of one group are directed in the opposite direction relative to the brackets of the other, and the rotor is made in the form of two end magnetic systems located on different sides of the stator, each of which is formed by a “p” ferromagnetic elements that are in the form of U-shaped staples, evenly spaced around the circle with a step equal to the pitch of the stator staples and forming closed magnetic circuits with them, having a longitudinal section of the generator in the form of an integral twisted magnetic circuit divided into two parts by an air gap and -shaped ferromagnetic brackets of one end rotor magnetic system are oriented counter to brackets of its other end magnetic system.

In addition, in a synchronous electric generator, the end magnetic systems can be mounted with a 1/3 tooth division of the stator relative to each other, their ferromagnetic elements are fully or partially made of magnetically hard material and are installed after their magnetization in such a way that they form a system of alternating circles magnetic poles.

The invention is illustrated by drawings, where Fig. 1 shows longitudinal and transverse sections of a single-phase generator with electromagnetic excitation, in Fig. 2 an integral magnetic circuit, from which, after cutting, the elements of the magnetic systems of the stator and rotor are obtained. Figure 3, 4., 5, shows the elements, the introduction of which into the design of the generator expands its functionality to the ability to generate not only single-phase, but also three-phase alternating current without losing the waste-free technology for its manufacture.

The synchronous electric generator contains a windingless rotor 1, three stator windings 2, 3 and 4 and 2p installed coaxially with the shaft and uniformly spaced around the circumference of U-shaped ferromagnetic brackets 5 and 6, the middle 3 and one of the side stator windings 4 being covered by one group of p "located through one ferromagnetic staples 5, and the middle 3 and the other lateral stator winding 2 is covered by another group of" p "ferromagnetic staples 6 and these groups of staples are shifted along the axis by at least the width of the middle stator winding 3. U-shaped ferro the stator magnetic brackets 5 and 6 are oriented at their ends along the axis of the O-O generator. In this case, the brackets 5 of one group are directed in the opposite direction relative to the staples 6 of their other group. The rotor of the generator 1 is made in the form of two end magnetic systems located on opposite sides of the stator. Each of the magnetic systems of the rotor 1 is formed by a “p” ferromagnetic elements, made in the form of U-shaped brackets 7 and 8, made of soft magnetic material and uniformly placed around the circumference on disks 10 mounted on the shaft 9 with a step equal to the pitch of the stator groups and forming with them, when placing their ends opposite the ends of the stator brackets, closed magnetic circuits having in the longitudinal section of the generator a view of an integral twisted magnetic circuit 11 (Fig. 2), divided into two parts (5 and 7 in Fig. 1) by an air gap δ, where P- figurative ferromagnetic brackets of one end rotor magnetic system are located opposite its other end magnetic system. Winding 3 (field winding) serves to create a magnetic field in the generator, and from windings 2 and 4 (armature windings), the electric energy generated in it is transformed into a load. The ferromagnetic brackets of the stator 5, 6, and rotor 7, 8 are made of twisted cores made of textured electrical steel tape using the manufacturing technology of twisted cores of magnetic amplifiers, chokes, and transformers. To exclude the generation of waste, the required sizes of ferromagnetic brackets are ensured by using for each size of the generator an appropriate choice of sizes of a template specially made for it, onto which the ferromagnetic tape is wound. The winding of the tape along the rolling direction and the coincidence of the magnetic field lines in the ferromagnetic brackets ensure maximum use of the magnetic properties of the steel.

The absence of angular displacement of the end magnetic systems of the rotor relative to each other eliminates the appearance of a variable component in the flux linkage and EMF of the excitation winding and distortion as a result of this shape of the generator voltage curve.

Synchronous electric generator operates as follows.

The operation of the generator is practically characterized by a periodic change in the magnetic conductivity of the air gap between the end surfaces of the U-shaped stator brackets and the ferromagnetic elements of the rotor during its rotation.

When placing the end surfaces of the stator and rotor brackets against each other, the conductivity of the air gap at the length of the stator pole division is maximum, and after turning it half the stator pole division (when the end surfaces of the U-shaped rotor brackets are located between the end surfaces of the stator brackets) it is minimal. Pulsation frequency of magnetic conductivity during rotor rotation

f = pn / 60,

where n is the rotor speed.

With the same frequency, without changing sign (direction), the magnetic flux pulsates in each U-shaped stator bracket and the flux linkage of windings 2 and 4. Magnetic flux penetrating the cross section of the field winding 3, due to the shift of the alternating components of the magnetic flux in the opposite direction of the ferromagnetic brackets stator by 180 electrical degrees, does not depend on the angle of rotation of the rotor and is equal to the sum of the constant components of the magnetic fluxes in the stator ferromagnetic brackets facing the same direction.

To expand the scope of the utility model, which is limited by the power supply systems of single-phase alternating current, it is possible to completely preserve the structural elements and their relative position in the generator, to move the end magnetic systems of the rotor by one third of the pole division of the stator and the ferromagnetic elements of these systems to complete, or in whole or in part hard magnetic material (from alloys of permanent magnets) with their installation after magnetization in place of staples made of soft magnetic material, and so that a system of alternating poles is formed around the circumference. In this case, the stator ferromagnetic brackets are made by cutting the twisted core with the corresponding dimensions into two equal parts, and the field winding 3 in it is made with the same number of turns and the same sizes as windings 2 and 4. Together, the windings 2, 3 and 4, when a permanent magnet generator is introduced into the magnetic circuit and connected to a star or triangle, they form a three-phase winding.

FIGS. 3, 4 and 5 show, by way of example, the arrangement and orientation of the poles of the permanent magnets 12 on the surface of the disks 10 facing the ends of the stator brackets and the structural versions of the ferromagnetic rotor brackets in their manufacture in full (FIG. 4) and partially (FIG. 5) from alloys of permanent magnets. 6 is a vector diagram explaining the principle of formation of a three-phase winding in a generator with excitation from permanent magnets. 7 shows an electrical diagram of the connection of the windings 2, 3 and 4 in a star.

The permanent magnets 12 in FIGS. 3 and 4 are made integral in the form of U-shaped brackets, and in FIG. 5 they are prismatic in shape with the yoke 13 connecting them. When performing rotor disks 10 of ferromagnetic material, they perform the yoke functions for all located on each of permanent magnets

The transformation of the generator’s magnetic system from single-phase to three-phase by simply replacing soft magnetic ferromagnetic material with hard magnetic material when the rotor end magnetic systems are shifted by a third of the pole division of the stator is due to the fact that the magnetic flux variation curves coupled to the turns of ω ₂ and ω _{4 of} windings 2 and 4 are shifted relative to each other 120 electrical degrees, and the curve of change of magnetic flux linked with the coil windings ₃ w 3 of smaller radius hugging circumferentially distributed and oriented tm eh axis of the generator stator portions ferromagnetic brackets, with equal amplitude with them is offset with respect to each of these curves by 60 electrical degrees, and its amplitude is equal to the amplitudes of these curves. The vectors EMF of the windings are shifted by the same angles. The diagram of EMF vectors shown in FIG. 6 determines their relative position with the same orientation of the direction of their winding relative to the axis of the machine. To obtain a symmetric three-phase system of EMF vectors in this case, it is enough to take the end of the winding 3 as the beginning of the winding when connecting the windings to a star or triangle.

The frequency of the current generator with excitation from permanent magnets is half the frequency of the current of the generator with electromagnetic excitation with the same number of ferromagnetic elements of the end systems of the rotor, and the degree of use of the magnetic flux and active materials is higher due to the absence of a constant component of the magnetic flux in the magnetic circuit.

Using the utility model allows to obtain minimal losses in steel, due to the performance of the ferromagnetic elements of the rotor laden and the closure of the eddy currents across the sheets. In addition, this ensures almost one hundred percent use of the ferromagnetic material of the workpieces in the manufacture of the magnetic circuit and the maximum use of its magnetic properties.

Claims (2)

1. A synchronous electric generator containing a windingless rotor, a stator formed by three windings mounted coaxially with the shaft and an even number equal to 2p, uniformly spaced around the circumference of the U-shaped ferromagnetic staples, the middle and one of the side stator windings covered by one group of p located through one ferromagnetic staples, the middle and other lateral stator windings are covered by another group of p ferromagnetic staples, and these groups of staples are shifted along the axis by at least the width of the stator winding, characterized in that the U-shaped brackets are oriented at their ends along the machine axis and the brackets of one group are directed in the opposite direction relative to the brackets of the other, and the rotor is made in the form of two end magnetic systems located on different sides of the stator, each of which is formed by p ferromagnetic elements, also having the shape of U-shaped staples uniformly spaced around the circle with a step equal to the staples of the stator groups, and forming closed magnetic circuits with them, having in the longitudinal section of the generator a holistic a twisted magnetic circuit, divided into two parts by an air gap, and the U-shaped ferromagnetic brackets of one end magnetic system of the rotor are located opposite the ferromagnetic brackets of its other end magnetic system. 2. The synchronous electric generator according to claim 1, characterized in that the end magnetic systems are mounted with a 1/3 shift of the stator relative to each other, their ferromagnetic elements are fully or partially made of magnetically hard material and are installed after their magnetization in such a way that form a system of magnetic poles alternating around the circumference.

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