RU2392724C1 - Single-phased electric generator - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to the field of electric engineering, in particular to single-phased electric generators with electromagnetic excitation executed via contact rings directly from source of DC voltage and may be used in autonomous systems of electric equipment, in automatics and household appliances, on aviation and motor transport, as wind power generators, high-frequency electric generators, synchronous converters of single-phase alternating current frequency, and also in rectification of alternating EMF with the help of uncontrolled and controlled semiconductor valves - as DC generators, contactless exciters of synchronous generators of mobile mini-power stations and low-capacity power stations. Proposed single-phase electric generator comprises stator, anchor core of which is assembled from insulated sheets of electrotechnical steel with high magnetic permeability and has explicit poles with coil single-phase winding of anchor, each coil of which is arranged on according explicit pole of anchor, and rotor comprising inductor with even and odd cores with identical number of explicit poles on each core, even and odd cores of inductor are arranged in the form of packets assembled from insulated sheets of electrotechnical steel with high magnetic permeability, number of inductor cores is at least two, even inductor cores are displaced relative to odd ones in tangential direction by half of pole division of inductor core, inductor cores are placed onto magnetic conductor of inductor, between cores of inductor there are ring-like coils of inductor excitation winding arranged as supplied by DC (rectified) current via brushes and contact rings. At the same time certain ratios must be maintained between number of explicit poles of anchor, number of explicit poles on each inductor core, width of pole arc of explicit anchor poles and width of pole arc of explicit poles of each inductor core.

EFFECT: provides for high power and operational indices of single-phased electric generator.

12 cl, 6 dwg

Description

The invention relates to electrical engineering, in particular to single-phase electric generators with electromagnetic excitation, carried out through slip rings and directly from a constant voltage source, and can be used in stand-alone electrical equipment systems, in automation and household appliances, in aviation and automobile transport, as wind generators , high-frequency electric generators and synchronous frequency converters of single-phase alternating current, as well as when rectifying AC th EMF with the help of uncontrolled and controlled semiconductor gates - as direct current generators, contactless exciters of synchronous generators of mobile mini-power plants and small power plants.

Known designs of synchronous machines with a three-phase winding of the armature and the excitation winding of the inductor (Ivanov-Smolensky A.V. Electric machines: Textbook for high schools. - M .: Energy, 1980. P. 490 ÷ 513). The armature is carried out by an implicit pole carrying a three-phase distributed opposite pole p-period winding, the inductor is carried out by an explicit pole or non-polar pole carrying a opposite pole p-period field winding. Electrical communication with the power source is carried out directly and using a brush-contact unit. Synchronous machines are most widely used, in which the armature winding is connected to the load (in generator mode) or to a three-phase voltage source (in motor mode) directly, and the inductor excitation winding is connected to slip rings and connected to a constant voltage source through sliding contacts using brushes . Low-power synchronous machines can also be manufactured in reverse design, when electrical contact with the field winding is carried out directly, and with the armature winding through the brush-contact unit. The disadvantage of these electric machines is the difficulty of performing a distributed winding of the armature, which has less reliability compared to the coil concentrated winding of the armature.

Known adopted for the prototype superconducting valve induction machine (Patent RU 2178942 C1, IPC 7 H02K 55/00, H02K 55/02, authors: Kovalev L.K., Ilyushin K.V., Poltavets V.N., Semenikhin BC, Penkin V.T., Kovalev K.L., Egoshkina L.A., Larionov A.E., Koneev S.M.-A., Modestov K.A., Larionov S.A.), containing a stator with a lined core a multiphase coil winding located on its pole projections, a cylindrical rotor comprising a lined core with pole projections, provided with a second stator with a lined core, on which pole protrusions a multiphase coil winding is located, and a second rotor located on the same shaft as the first rotor, on the shaft between the two rotors is a cylindrical insert of high-temperature superconducting (HTSC) material with a “frozen-in” magnetic flux, which is a cryomagnet magnetized in the axial direction and providing unipolarity of the pole protrusions of the first and second rotors, a solenoid is installed on the stators, covering the above-mentioned cylindrical insert for “freezing” magnetic field into it current, the stators are connected by a cylindrical magnetic circuit, and their multiphase coil windings are equipped with a switch that provides unipolar magnetization of the poles of each stator, different polarity of the poles of the first and second stators, the coincidence of the direction of the magnetic flux in the poles of the stators with the direction of the magnetic flux of the above insert, and the alternating turns of the coil windings of each phase in a given sequence. The disadvantage of the described technical device is the complexity of the rotor design, the presence of two stators with a solenoid between them, each stator has its own multiphase armature winding, low maintainability when any of the windings is broken due to the location of all the windings (armature and excitation) only on the stator.

The aim of the present invention is to provide a new, simple, reliable, technologically advanced and highly repairable design of a single-phase electric generator with high energy performance.

The objective of the present invention is the optimal choice of the number of poles of the armature, the number of poles of the inductor, the optimal width of the pole arc of the poles of the armature and the pole arc of the poles of the inductor, the definition of the connection circuit of the coils focused on the poles of the armature, single-phase coil winding of the armature of a single-phase electric generator.

The technical result of the present invention is to obtain a reliable and technological design with high energy performance and operational characteristics of a single-phase electric generator. To this end, the stator contains a lined core of the armature with distinct poles, a single-phase coil winding of the armature, the coils of which are placed on the corresponding distinct pole of the armature, one at each pole, coils of the single-phase armature coil are magnetically connected, the rotor contains an odd inductor and even cores with the same number of pronounced poles on each core, the cores of the inductor are made in the form of packets drawn from insulated sheets of electrical hoists with high magnetic permeability, the number of inductor cores is at least two, the active length of the end cores of the inductor in the axial direction is the same, in the presence of packages of the inductor more than two, the active length of the cores of the inductor in the axial direction located between the end cores of the inductor is two times the active length inductor cores, even inductor cores are offset relative to the odd inductor cores in the tangential direction by half of the pole division of the core inductor, inductor cores are pressed onto the sleeve, which is the inductor’s magnetic circuit, made of soft magnetic steel with high magnetic permeability and mounted on the non-magnetic rotor shaft, pronounced armature poles and pronounced inductor poles are facing each other and separated by an air gap, between the inductor cores there is a winding excitation of the inductor, made in the form of ring-shaped coils covering the magnetic circuit of the inductor, the number of which is one less than the number of cores of the inductor, If there are more than one of them, the shaped coils of the inductor field winding are connected to each other so that, when a constant (rectified) current flows through them, the poles of the odd core of the inductor magnetize to form magnetic poles of the same polarity, for example, the southern “S”, and the poles of even core of the inductor magnetizing, form a magnetic pole of the other polarity, for example north «N», the number of armature poles express determined by the equation: Z _1P = 2 · k, the number of salient poles each cardiac Single inductor defined by the equation: Z _2P = k, where k = 2, 3, 4, 5, ... - a positive integer, beginning with two pole arc width express armature poles in the angular dimension defined by the expression b _1P = (0,76 ÷ 1,0) · t _1P , the width of the pole arc of the pronounced poles of each inductor core in the angular measurement is determined by the expression: b _2P = (0.38 ÷ 0.5) · t _2P , with t _1P = 360 ° / Z _1P represents the pole division of the pronounced poles of the armature in an angular dimension, t _2P = 360 ° / Z _2P represents the pole division of the pronounced poles of each core inductor in angular measurement.

In the present invention, it is possible to design a single-phase electric generator with both an external armature, which is a stator, and an internal inductor, which is a rotor, and with an internal armature, which is a rotor, and an external inductor, which is a stator (for example, for a synchronous generator exciter with rotating semiconductor rectifier devices ) In the first case, the inductor can be excited when the field winding is supplied with direct (rectified) current through brushes and contact rings directly from the DC voltage source or from the rectified voltage source, and can also be carried out when the field winding is supplied with rectified current from the armature winding during rotation of the generator rotor through semiconductor rectifier device, brushes and slip rings (principle of self-excitation). In the second case, the inductor is excited by supplying the field winding with a constant (rectified) current either directly from a constant voltage source or from a rectified voltage source. In this case, a single-phase electric generator when used as a pathogen of a synchronous generator with a rotating semiconductor rectifier device is non-contact.

The invention is illustrated by drawings:

figure 1 is a General view with a longitudinal section of a single-phase electric generator with an external armature, which is a stator, and an internal inductor, which is a rotor,

figure 2 is an example implementation of the invention in the form of cross sections of the cores of the armature and inductor when a constant (rectified) current flows through the field winding (active inductor),

figure 3 - connection diagram of the coils of a single-phase armature winding when receiving a variable EMF of the armature at the output when the excitation winding of the inductor is powered from a constant voltage source,

figure 4 - connection diagram of the coils of a single-phase armature winding when receiving alternating voltage at the output of the generator when feeding the excitation coil of the inductor from the armature winding through uncontrolled semiconductor rectifiers, brushes and contact rings,

5 is a diagram of the connection of the coils of a single-phase armature winding when receiving a constant (rectified) voltage at the generator output through uncontrolled semiconductor rectifiers when feeding the excitation coil of the inductor from the armature winding through uncontrolled semiconductor rectifiers, brushes and contact rings,

6 is a diagram of the connection of the coils of a single-phase armature winding when receiving a constant (rectified) EMF at the output of the generator through uncontrolled semiconductor rectifiers when feeding the inductor winding directly from a constant voltage source.

Figure 2 shows the position of the core of the inductor relative to the core of the armature at that time when the maximum EMF is induced in the coils of the single-phase armature winding, the direction of which in each coil is shown by arrows in figure 3 ÷ 6.

In Fig. 4 ÷ 6, in the electric circuit parallel to the output of uncontrolled semiconductor rectifiers to smooth the ripple of the output voltage (Fig. 4, Fig. 5) and the output EMF (Fig. 6) of the generator, the capacitor “C” is turned on.

In Fig. 3 ÷ 6, a rheostat R _B is included in the electric circuit of the field winding to control a constant (rectified) field current.

In Fig.1 ÷ 6, the letters and numbers indicate the coils of a single-phase armature winding located at the corresponding poles of the armature. For example, A3 is a phase “A” coil located at the third pole of the armature.

Consider the design of a single-phase electric generator with an external armature, which is the stator, and an internal inductor, which is the rotor (figure 1, figure 2). Anchor core 2 remagnetized with a high frequency is made of batch made of electrical steel with high magnetic permeability and is pressed into the magnetic circuit 1, which is a body made of steel with high magnetic permeability. The core 2 of the armature has pronounced pole 3 of the armature, on which the single-phase coil winding of the armature is located, made by coils 4 located on the corresponding distinct pole of the armature 3, one at each pole. Coils 4 of a single-phase armature winding are made of a winding copper wire or a winding copper bus. Coils 4 of a single-phase armature winding can be interconnected in series, parallel and mixed, but always magnetically, i.e. so that when the electric currents flow through the coils 4, the pronounced poles 3 of the armature form an alternating polarity of the magnetic poles in the air gap. The inductor with bearings 15, shaft 5 and bearing shields 16 is positioned relative to the armature. The shaft 5 is made of non-magnetic steel or titanium. A sleeve 6 is mounted on the shaft 5, made of steel with high magnetic permeability and which is the magnetic circuit of the inductor. Odd 7 and 9 and even 8 inductor cores are pressed onto sleeve 6. The active length of the two extreme cores 7 and 9 of the inductor in the axial direction is the same, the active length of the core 8 of the inductor between them in the axial direction is twice the length of the extreme cores 7 and 9. The cores 7, 8 and 9 of the inductor are packages drawn from isolated sheets of electrical steel with high magnetic permeability, and have the same number on each core evenly distributed around the circumference of pronounced poles 10. In order to reduce the cost of the design, the cores 7, 8 and 9 nduktora metal processing can be performed from a single piece of steel with high magnetic permeability. In this case, they can be manufactured with a sleeve 6 as a single part. An even 8 core of the inductor is offset relative to the odd 7 and 9 core of the inductor in the tangential direction by half the pole division of the core of the inductor. Between the cores 7, 8 and 9 of the inductor is located the excitation coil of the inductor, made in the form of two ring-shaped coils 11 and 12 spanning the magnetic core of the inductor, interconnected as shown in Figs. 3 ÷ 6.

Consider the operation of a single-phase electric generator (figure 1 ÷ 3).

A constant voltage is supplied from the DC voltage source to the field coil of the inductor through brushes and contact rings. A constant electric current flows through the excitation winding of the inductor, magnetizing the odd poles of the inductor with one polarity, for example, the southern “S”, and the even poles of the inductor with the other polarity, for example, the northern “N”. When the rotor rotates with an external source of torque with a rotation frequency n, the constant magnetic flux of the inductor created by the direct current flowing through the annular coils 11 and 12 of the inductor excitation coil penetrates the air gap and the pronounced pole 3 of the armature from the side of the inductor, then from the side of the armature, creating this in the pronounced poles of the 3 armature variable magnetic flux, inducing in the coils 4 of a single-phase winding of the armature EMF time-variable. The direction of the induced EMF in each coil 4 of the single-phase armature winding at a point in time corresponding to the position of the inductor cores relative to the armature core (Fig. 2) is shown by arrows in Figs. 3 ÷ 6. The variable EMF of the single-phase armature winding is equal to the sum of the induced EMF in each coil 4. If the external circuit - the load circuit is closed, then alternating electric current flows through the single-phase winding of the armature, the electric power is given to the consumer. The frequency f (Hz) of the variable EMF of the single-phase armature winding is related to the rotational speed n (r / min) of the rotor and is determined by the equation: f = n · Z _2P / 60.

It should be noted that in the described generator during operation the magnetic flux of excitation of the inductor remains constant at any position of the rotor due to the selected ratios of the width of the pole arc of the pronounced pole of the armature and the pole division of the explicit pole of the armature and the width of the pole arc of the pole of the inductor and pole division of the explicit pronounced poles of each core of the inductor. When the generator is operating under load, an alternating current flows through the armature winding, creating in the pronounced poles of the armature core the armature reaction magnetic field, which closes through the air gap, pronounced inductor poles, cores and inductor magnetic circuit in the radial direction, without inducing inductor excitation coils EMF of the armature reaction and without creating overvoltages in the field winding of the inductor (especially with a sharply variable and “shock” load in the generator short circuit mode). toyatelstvo is one of the determinants of high reliability structure described single-phase electrical generator.

Claims (12)

1. A single-phase electric generator containing a stator with a lined core with distinct poles and a concentrated armature winding made in the form of coils spanning the stator poles, and a rotor containing lined cores, characterized in that the stator contains a lined armature core with distinct poles and a single-phase coil winding of the armature, the coils of which are located on the corresponding clearly defined poles of the armature, one at each pole, the coils of the single-phase armature winding are interconnected according to a magnetic relation, the rotor contains an inductor with odd and even cores with the same number of distinct poles on each core, the cores of the inductor are made in the form of packets drawn from insulated sheets of electrical steel with high magnetic permeability, the number of cores of the inductor is at least two, the active length axial direction of the inductor core is the same; even inductor cores are offset relative to the odd inductor cores in the tangential direction by half of the pole division of the inductor core, the inductor cores are pressed onto the sleeve, which is the inductor’s magnetic circuit, made of magnetically soft steel with high magnetic permeability and mounted on the non-magnetic rotor shaft, pronounced armature poles and pronounced inductor poles face each other and are separated by an air gap, between the core of the inductor is located the excitation coil of the inductor, made in the form of ring-shaped coils covering the magnetic circuit of the inductor, the number of which is one before the number of inductor cores, the ring-shaped coils of the excitation coil of the inductor, if there are more than one, are interconnected in such a way that, when a constant (rectified) current flows through them, the poles of the odd cores of the inductor magnetize to form magnetic poles of the same polarity, and the poles of even cores of the inductor, being magnetized, they formed magnetic poles of a different polarity, the electrical connection of the field coil of the inductor with the source of constant (rectified) voltage provides I through slip rings and brushes, the number express armature poles is defined by the equation: Z _1P = 2 · k, the number of each core inductor poles express determined by the equation: Z _2P = k, where k = 2, 3, 4, 5, ... - a positive integer starting from two, the width of the pole arc of the pronounced anchor poles in the angular dimension is determined by the expression b _1P = (0.76 ÷ 1.0) · t _1P , the width of the pole arc of the pronounced poles of each inductor core in the angle dimension is determined by the expression : b _2P = (0.38 ÷ 0.5) · t _2P , while t _1P = 360 ° / Z _1P represents the pole the division of the pronounced poles of the armature in the angular dimension, t _2P = 360 ° / Z _2P is the pole division of the pronounced poles of each core of the inductor in the angular dimension. 2. The single-phase electric generator according to claim 1, characterized in that when there are more than two inductor packets, the active length of the cores in the axial direction between the extreme cores of the inductor is two times the active length of the extreme cores. 3. The single-phase electric generator according to claim 1, characterized in that the armature is located outside and is a stator, the inductor is inside and is a rotor. 4. The single-phase electric generator according to claim 1, characterized in that the armature is located inside and is a rotor, the inductor is outside and is a stator. 5. The single-phase electric generator according to claim 1, characterized in that the field winding of the inductor is powered directly from a constant (rectified) voltage source. 6. The single-phase electric generator according to claim 1, characterized in that the field winding of the inductor is powered by a single-phase armature winding through semiconductor rectifiers, brushes and slip rings. 7. The single-phase electric generator according to claim 1, characterized in that in the presence of inductor cores of more than two coils of the field winding of the inductor are interconnected in series. 8. The single-phase electric generator according to claim 1, characterized in that in the presence of inductor cores more than two coils of the field coil of the inductor are connected together in parallel. 9. The single-phase electric generator according to claim 1, characterized in that in the presence of an odd number of cores of the inductor more than three coils of the field winding of the inductor are interconnected mixed. 10. The single-phase electric generator according to claim 1, characterized in that the armature winding coils are interconnected in series. 11. The single-phase electric generator according to claim 1, characterized in that the armature winding coils are interconnected in parallel. 12. The single-phase electric generator according to claim 1, characterized in that the armature winding coils are interconnected mixed.

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