RU191977U1 - HIGH-TURNING ELECTRIC INDUCTOR TYPE MACHINE - Google Patents

Abstract

The utility model relates to the field of electrical engineering, in particular, to the design of high-speed electric machines of inductor type, and can be used in the field of electric power generation facilities based on high-speed microturbines. The technical result of the utility model is the development of a high-speed electric inductor-type machine with high performance and a high level of reliability. The technical result of the utility model is achieved using a high-speed electric inductor-type machine containing a stator, consisting of a stator magnetic circuit and active stator packets, an implicit pole rotor and an excitation coil installed inside the stator magnetic circuit and covering an implicit pole rotor, which is an unshaped cylindrical part with 2 longitudinal through holes filled with non-magnetic material, and the active packets do not have a pronounced pole structure in the groove where the distributed stator windings are installed, the length of the implicit pole rotor being 15% longer than the length of the stator magnetic circuit, while the longitudinal through holes of the implicit pole rotor are a closed figure made in the form of a circle sector with an arc angle of more than 180 degrees, as well as mates between the arc and the chord with symmetrical cross sections relative to the diameter of the cross section of the implicit pole rotor, and the chords forming their cross sections are parallel to each other and are located closer to a circle that forms the external cross-sectional shape of the implicit pole rotor than the centers of the arcs forming their cross-sections.

Description

The utility model relates to the field of electrical engineering, in particular, to the design of high-speed electric machines of inductor type and can be used in the field of electric power generation facilities based on high-speed microturbines.

A non-contact induction electric machine with combined excitation is known (RU 2390086), comprising a stator with a casing of soft magnetic material with stator packets fixed to it from the insulated sheets of electrical steel with high magnetic permeability, a coil m-phase armature winding, an inductor excitation coil located between stator packages, non-magnetic shaft with a sleeve, burnt from insulated sheets of electrical steel with high magnetic permeability, rotor packages, number which are equal to the number of stator packets, characterized in that the stator and rotor packets are divided into even and odd, the number of stator packets is at least two, the active length of the extreme stator and rotor packets in the axial direction is the same, the stator packets contain clearly expressed uniformly distributed over the cylindrical surface poles, on the inner surface of which elementary teeth are made, the number of pronounced poles on each stator package is the same, the number of elementary teeth on each pronounced pole of the package with the stator in the same way, the stator packets in the tangential direction are located so that the axes of their clearly opposite poles opposite each other in the axial direction coincide, the odd and even rotor packets are pressed onto the corresponding odd and even rotor magnetic cores, which are mounted on a non-magnetic sleeve mounted on the shaft , the rotor packets contain teeth evenly distributed over the cylindrical surface, the number of which is the same on each rotor packet, the even rotor packets are offset relative to even packages of the rotor in the tangential direction by half the tooth division of the package of the rotor, between the magnetic circuits of the rotor there are annular layers of axially magnetized permanent magnets in one direction, the number of annular layers of permanent magnets is one less than the number of packages of the rotor, m-phase coil is concentrated on the pronounced poles of the stator packets armature winding, each coil of which in the axial direction covers the corresponding distinct poles of the even and odd stator packets, one explicitly the expressed pole of each package, the number of phases of the coil of the m-phase armature winding m = 3, 4, 5, 6, the field coil of the inductor made in the form of ring-shaped coils with a longitudinal axis that coincides with the longitudinal axis of the machine, the number of ring-shaped coils of the field coil of the inductor by one fewer stator packets.

The disadvantages of a non-contact gear electric machine with combined excitation include the complexity of manufacturing the rotor and stator of the machine with a large number of teeth with high requirements for manufacturing accuracy, which leads to an increase in the cost of the electric machine. Also, with a high rotor speed, the disadvantages include the installation of ring permanent magnets on the rotor. The use of permanent magnets leads to the need to install additional fasteners, providing a firm fit of the magnets on the rotor, which leads to a serious increase in the cost of the electric machine as a whole.

The prototype of the utility model is a two-pack axial inductor generator (USSR patent No. 1815751) containing a longitudinally charged stator and rotor, a multiphase stator winding located on each packet, and an excitation source, in order to increase the specific power, the stator is made of two separate packets, the excitation source is placed between the stator packets and is made in the form of an axially magnetized annular permanent magnet, an additional one is placed between each end side of the annular magnet and the stator packet ADDITIONAL twisted split magnetic core, wherein the radial slits formed in the magnetic cores at a pitch equal to twice the step the stator windings are in mutually perpendicular planes.

The disadvantages of the prototype include the complexity of the design of the rotor with clearly defined teeth with high aerodynamic resistance of the protruding teeth at high rotational speeds of the rotor. The disadvantages of the two-pack axial inductor generator include the need to fasten the active parts of the rotor in the grooves, which, when used in high-speed electric machines due to the high mechanical centrifugal loads in the rotor, is a very difficult technical task, the implementation of which is possible only with the use of expensive materials and manufacturing technologies, the use of which in turn leads to an increase in the cost of the entire machine as a whole.

The objective of the utility model is the development of a high-speed electric induction machine for use in high-speed turbine-based electrical energy generation systems.

The technical result of the utility model is the development of a high-speed electric induction machine with high performance characteristics.

The technical result of the utility model is achieved using a high-speed induction-type electric machine containing a stator, consisting of a stator magnetic circuit and active stator packets, an implicit pole rotor and an excitation coil installed inside the stator magnetic circuit and covering an implicit pole rotor, which is an unshielded cylindrical part with 2 longitudinal through holes filled with non-magnetic material, and active packets do not have a pronounced pole structure in the groove of which the distributed stator windings are installed, the length of the implicit pole rotor being 15% longer than the length of the stator magnetic circuit, while the longitudinal through holes of the indirect pole rotor are a closed figure made in the form of a circle sector with an arc angle of more than 180 degrees, as well as mates between the arc and the chord , with symmetric cross sections relative to the diameter of the cross section of the implicit pole rotor, and the chords forming their cross sections are parallel to each other and are closer to the prices a circle of a circle forming an external cross-sectional shape of an implicit pole rotor than the centers of arcs forming their cross-sections.

In FIG. 1 shows a sketch of a general view of a high-speed electric machine of induction type with a longitudinal and transverse section, in FIG. 2 is a sketch of the rotor of a high-speed electric machine of inductor type, in FIG. 3 shows a cross section of a rotor of a high speed electric induction machine with a cross section through holes.

A high-speed electric inductor type machine contains a stator (not shown in FIG.), An implicit pole rotor 1 and an excitation coil 2. The stator (not shown in FIG.) Consists of active stator packets 3 (not shown in FIG.) Without a pronounced pole structure , with grooves on the surfaces facing the implicitly rotor 1, in which the distributed stator windings 4 are installed (not indicated in FIG.), and the stator magnetic circuit 5 (not indicated in FIG.). Implicit pole rotor 1 is a non-lined cylindrical part with 2 longitudinal through holes 6 and filled with non-magnetic material, for example, aluminum. The longitudinal through holes 6 are made in the end parts of the implicit pole rotor 1 along the axis of rotation. The cross section of each of the longitudinal through holes 6 of the implicit pole rotor 1 is a closed figure made in the form of a sector of a circle with an arc angle of more than 180 degrees and the mates between the arc and the chord. The cross-sections of the longitudinal through holes 6 are symmetrical with respect to the diameter of the cross section of the implicit pole rotor 1. The longitudinal through holes 6 of the indirect pole rotor 1 are made so that the chords forming their cross sections are parallel to each other and are located closer to the center of the circle forming the external shape of the cross section of the non-pole pole 1 than the centers of their cross-section arcs forming them, while the distance X between the chords forming their cross-section should not less than 35% of the diameter D of the cross section of the implicit pole rotor 1, and the distance Y between the outer surface of the rotor 1 and the through hole 6 cannot be less than 1% of the diameter D of the cross section of the implicit pole rotor 1. The area and position of the cross sections of the longitudinal through holes 6 of the implicit pole the rotor 1 is selected so as to ensure the strength of the non-polar pole rotor 1 in the entire range of microturbine rotation frequencies. The length of the implicit pole rotor 1 is 15% longer than the length of the stator magnetic circuit 5 (not indicated in FIG.). The excitation coil 2 is installed inside the stator magnetic circuit 5 (not shown in FIG.) And covers the non-polar rotor 1. The active stator packages 3 (not shown in FIG.) Have a cylindrical outer surface facing the stator magnetic circuit 5 (not shown in FIG.) And are installed in the inner cylindrical part of the stator magnetic circuit 5 (not indicated in Fig.). The stator magnetic circuit 5 (not indicated in FIG.) Has a cylindrical surface along the inside and is made of soft magnetic material, for example, electrical steel. The outer end surfaces of the active stator packets 3 (not shown in FIG.) And the end surfaces of the stator magnetic circuit 5 (not shown in FIG.) Are combined.

Consider the operation of a high-speed electric machine of inductor type. When a direct current is supplied to the excitation coil 2 in an implicit pole rotor 1, a magnetic flux begins to flow, the lines of tension of which will be directed along the axis of rotation of the implicit pole rotor 1. Due to the presence of 2 longitudinal through holes in the implicit pole rotor 1, the density of magnetic field lines will be uneven in it section. The use of longitudinal through holes 6 of the implicit pole rotor 1 allows you to create different values of magnetic resistance in different radial directions of the cross section of the implicit pole of the rotor 1, while the value of magnetic resistance will be higher in areas with a smaller area of soft magnetic material. The cross-sectional shape of the longitudinal through holes 6 of the implicit pole rotor 1 makes it possible to achieve a change in the magnetic resistance of the non-pole pole rotor 1 in various radial directions close to sinusoidal. The magnetic flux flowing out of the implicit pole rotor 1 through the air gap (not shown in FIG.) Flows into the active stator packets 3 (not shown in FIG.) And the distributed stator windings 4 (not shown in FIG.) Are subsequently closed through the stator magnetic circuit 5 ( in Fig. is not indicated) high-speed electric machine inductor type.

When a rotation of an implicit pole rotor 1 occurs under the influence of external mechanical forces in the active packages 3 of the stator (not indicated in FIG.), Alternating magnetic fields arise due to different magnetic resistance of the implicit pole rotor 1 in different radial directions. Due to the high speed of rotation of the implicit pole rotor 1, the proposed design of the implicit pole rotor 1 with 2 longitudinal through holes 6 provides a sufficient amplitude of the sinusoidal component of the magnetic field in the active packets 3 of the stator (not shown in Fig.). An alternating magnetic field of sufficient amplitude and frequency provides high EMF values generated in the distributed stator windings 4 (not indicated in FIG.). The proposed design of a high-speed electric machine of inductor type allows to ensure its high performance.

The use of distributed stator windings 4 (not indicated in FIG.) Allows the use of active stator packages 3 (not indicated in FIG.) Not having clearly defined poles, which makes it possible to create an inner surface close to cylindrical and thereby ensure low aerodynamic drag of the stator (on Fig. not indicated). Also, the use of an implicit pole rotor 1 in the form of a non-lined cylindrical part allows minimizing its aerodynamic drag and minimizing aerodynamic losses in a high-speed electric induction machine as a whole, as well as improving heat dissipation from its internal parts.

The above described features of a high-speed electric machine of inductor type make it possible to ensure its high operational characteristics.

Also, the use of the proposed design of a high-speed electric machine of the inductor type provides a high level of reliability of the electric machine due to the use of an implicit pole rotor 1 and active stator packets 3 in the structure (not indicated in Fig.). The implementation of the implicit pole rotor 1 in the form of a non-lined cylindrical part allows to achieve sufficient rigidity, and also minimizes the number and amplitude of natural vibrations of the implicit pole rotor 1 in the working range of the microturbine rotation frequencies, which allows to increase the reliability of the electric machine by reducing the amplitude of the rotor vibrations during rotation . The use of active packages 3 of the stator (not indicated in Fig.) That do not have an explicit pole structure and an implicit pole rotor 1 in the form of a non-lined cylindrical part ensures high reliability of the electric machine at a high speed due to the absence of tooth structures on the rotor and the pole structure of the stator, which provides minimization of the possibility of separation of elements with the subsequent destruction of a high-speed electric machine inductor type.

Claims (1)

A high-speed electric inductor-type machine contains a stator, consisting of a stator magnetic circuit and active stator packets, an implicit pole rotor and an excitation coil installed inside the stator magnetic circuit and enclosing an implicit pole rotor, characterized in that the non-pole pole rotor is an unmounted cylindrical part with 2 longitudinal through holes filled with non-magnetic material, and the active packets do not have a pronounced pole structure, in the grooves of which are installed divided stator windings, and the length of the implicit pole rotor is 15% longer than the length of the stator magnetic circuit, while the longitudinal through holes of the indirect pole rotor are a closed figure made in the form of a circle sector with an arc angle of more than 180 degrees, as well as mates between the arc and the chord, with symmetrical cross sections relative to the diameter of the cross section of the implicit pole of the rotor, and the chords forming their cross sections are parallel to each other and are located closer to the center of the circle forming the external cross-sectional shape of the implicit pole rotor than the centers of the arcs forming their cross-sections.

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