RU2589730C1 - Three-input axial generator plant - Google Patents

Abstract

FIELD: machine building; electricity.

SUBSTANCE: three-input axial generator plant includes a housing accommodating photoelectric and thermal transducers, control unit, rotor position sensors with signal windings and excitation windings, side axial magnetic core with multiphase armature winding of main generator, side axial magnetic conductor with additional multiphase winding, inner axial magnetic conductor with multiphase armature winding of subexciter, main and additional single-phase excitation windings of exciter, rotor, on shaft of which by means of discs are rigidly fixed axial multipolar subexciter inductor with permanent magnets and axial rotary magnetic core with multiphase armature winding of exciter and single-phase excitation winding of main generator and three rectifiers, wherein on external radius of axial multipolar inductor of exciter with permanent magnets there are permanent magnets of rotor position sensor.

EFFECT: possibility for summation of different types of energy (mechanical, light, thermal).

4 cl, 4 dwg

Description

The invention relates to electrical engineering, in particular to electric machines, and is intended to summarize mechanical energy (for example, wind energy), light energy (for example, the light energy of the Sun with its preliminary conversion by photoelectric converters into direct current electric energy) and thermal energy (for example, thermal energy of the Earth or the Sun with a preliminary conversion of its thermal converter into electrical energy of direct current) with simultaneous conversion obtained total energy into high-quality direct current electric energy, and can be used to generate direct current electric energy for the needs of local facilities, such as farms, etc.

Known axial two-input non-contact electric machine-generator (US Pat. RF No. 2450411, authors Gait B.Kh., Kashin Ya.M. and others) containing a housing, exciter, pathogen and main generator mounted on the same shaft, while exciter consists of a permanent multi-pole magnet of the exciter exciter and a magnetic circuit with a winding of the exciter armature, the pathogen consists of a magnetic circuit with an excitation winding of the pathogen and a magnetic circuit with a winding of the exciter armature, the main generator consists of a magnetic circuit with the excitation winding of the main generator and the magnetic circuit with the winding of the armature of the main generator, while the permanent multipolar magnet of the exciter exciter and the magnetic circuits, in the slots of which the windings of the exciter, exciter and main generator are laid, are made axial, while the lateral axial magnetic circuits are rigidly installed in the housing, and the permanent the multi-pole magnet of the exciter inductor and the internal axial magnetic circuit are rigidly mounted on the shaft with the possibility of rotation relative to the side axial magnetic cores, while the permanent multipolar magnet of the exciter exciter is installed from the end of one side axial magnetic circuit, and the internal axial magnetic circuit is installed between the lateral axial magnetic circuits, the internal axial magnetic circuit and the lateral axial magnetic circuit, from the end of which there is a permanent multipolar magnet of the exciter exciter, are made with two active end surfaces with grooves, and the other lateral axial magnetic circuit is made with one ac an active end surface with grooves, while in the grooves of the lateral axial magnetic circuit with two active end surfaces from the side of the permanent multipolar magnet of the exciter, a multiphase winding of the exciter armature is laid, and on the opposite side, a single-phase excitation winding is connected, which is connected to the multipath sub-winding of the armature , and an additional excitation winding of the pathogen connected to a direct current source into the grooves internally on the axial magnetic circuit from the side of the exciter winding and the additional excitation winding of the pathogen laid multiphase winding of the exciter arm, and on the opposite side laid the single-phase excitation winding of the main generator, which is connected to the winding of the armature of the exciter through a multiphase two-half-wave rectifier, while in the grooves of the axial side axial an active end surface has a multiphase winding of the armature of the main generator.

However, known from US Pat. RF №2450411 an electric machine cannot summarize different types of energy (mechanical, light and thermal) coming from three different sources, with the simultaneous conversion of the received total energy into electrical energy, since it has only two inputs: one mechanical input - the rotor shaft, one electric - contacts for connecting an additional excitation winding of the pathogen.

Of the known technical solutions, the closest to the claimed invention in terms of technical nature and the technical result achieved is an axial non-contact motor generator (RF patent No. 2529210, authors Gait B.Kh., Kashin Y.M. et al.), Comprising a housing and a rotor, on which a permanent axial multipolar magnet of the exciter exciter and axial rotating magnetic circuits of the exciter and the main generator are installed, while in the case from the side of the permanent multipolar magnet of the exciter exciter A lateral axial magnetic circuit with one active end surface has been updated, in the grooves of which a multiphase winding is laid, and a permanent multipolar magnet of the exciter exciter is made with rotor position sensors, and each rotor position sensor consists of a sensing element mounted on a permanent multipolar magnet of the exciter exciter along the outer radius, and a signal winding installed by means of a rod on the inner surface of the housing on the line of intersection of a plane perpendicular to SI rotation of the rotor and passing through the axis of symmetry of the sensing elements, with the inner surface of the housing, with each signal winding equidistant from neighboring signal windings, and a control unit is installed in the lower part of the housing.

However, known from US Pat. RF №2529210 an electric machine cannot summarize different types of energy (mechanical, light and thermal) coming from three different sources, with the simultaneous conversion of the received total energy into electrical energy, since it has only one mechanical input - the rotor shaft.

The objective of the invention is the creation of a three-input axial generator set that allows you to summarize the energy coming from three dissimilar energy sources: mechanical energy, light energy and thermal energy, with the simultaneous conversion of the resulting total energy into high-quality direct current electric energy.

The technical result of the claimed invention is the summation of mechanical energy, light energy and thermal energy with the simultaneous conversion of the resulting total energy into high-quality direct current electric energy while improving the reliability of an electric machine.

The technical result is achieved by the fact that in the proposed three-input axial generator set containing a housing in which a control unit is installed, rotor position sensors, a signal winding and an excitation winding are located in the housing of each of them, a side axial magnetic circuit with a multiphase armature of the main generator armature, side axial magnetic circuit with an additional multiphase winding, an internal axial magnetic circuit with a multiphase winding of an exciter armature, the main and additional single-phase excitation windings of the pathogen, and a rotor on the shaft of which the constant axial multipolar magnet of the exciter exciter and an axial rotating magnetic circuit with a multiphase winding of the exciter armature and a single-phase excitation winding of the main generator are rigidly fixed to the shaft through the disks, while the constant axial multipolar magnet of the inductor with exciters is made rotor mounted on it along the outer radius, and the housing of the rotor position sensor with a signal winding and field winding is installed on the intersection line of the plane passing through the axis of symmetry of the permanent magnets of the rotor position and perpendicular to the axis of rotation of the rotor, with each rotor position sensor mounted on the inner surface of the housing by a rod and equidistant from adjacent rotor position sensors, and the rotor shaft is fixed in bearing units, closed by a cover on one side and extends beyond the housing on the other hand, while the single-phase excitation winding of the main generator is connected to full-phase winding of the exciter armature through a multiphase two-half-wave rectifier, the main single-phase excitation winding of the exciter is connected to a multiphase winding of the exciter arm through a multiphase half-wave rectifier, and the multiphase armature of the main generator arm is connected to the output multi-phase two-half-phase output of the upper part additional single-phase excitation winding of the pathogen, a heat converter is installed in the lower part of the casing, which can be connected to an additional multiphase winding through the control unit, and at the end of the rotor shaft that extends beyond the casing, a magnetic gearbox is installed, consisting of a shaft of a magnetic gearbox, drive and driven drives made of non-magnetic material , and permanent magnets placed on the master and slave disks with opposite poles towards each other, while the master disk is rigidly fixed to the shaft of the magnetic gear RA, and the driven disk is rigidly fixed on the rotor shaft of the three-input axial generator set, and the output multiphase two-half-period rectifier is made with the possibility of connecting to an external backup energy source - the battery, while the additional single-phase excitation winding of the exciter is configured to be connected to an external photoelectric converter, and additional multiphase winding is made with the possibility of connecting through the control unit to an external thermal Form.

The control unit of the proposed three-input axial generator set (TAGU) contains a differential-minimum relay, a power supply unit configured to connect via a differential-minimum relay to a heat converter, to an external heat converter, or to an external backup energy source - a storage battery - and having outputs of high level and low voltage level, and pulse forming units, one for each phase of the additional multiphase winding.

The backup power supply to the control unit is carried out from an external backup power source of the battery, which is not part of the control unit.

Each of the pulse generating units of the proposed TAGU contains the first, second, third, fourth and fifth limiting resistors, the first and second control transistors, the first and second pairs of switching transistors, and two transistors forming the “NOT” logic element.

The “NOT” logical element of each pulse forming unit of the proposed TAG through the fifth limiting resistor is connected to the low-level output of the power supply, and its input and the base of the first control transistor are connected to the signal winding of the rotor position sensor, while the base of the second control transistor is connected to the output of the logical element “ NOT, ”and the collectors of the first and second control transistors are connected to the low-level output of the power supply through the first and third limiting resistors, while the transformers of the first and second control transistors are grounded, and the bases of each pair of switching transistors are interconnected, while the bases of the first pair of switching transistors are connected to the collector of the first control transistor, and the bases of the second pair of switching transistors are connected to the collector of the second control transistor, while the collectors of switching transistors one of each pair is connected to the high-level output of the power supply, and their emitters through the second and fourth limiting resistors in are connected to the corresponding terminals of the corresponding phase of the additional multiphase winding and to the collectors of the switching transistors of another pair.

The present invention, in contrast to the prototype, allows you to ensure using one axial electric machine the summation of the energy coming from three dissimilar energy sources: mechanical energy, light energy (with its preliminary conversion by a photoelectric converter into direct current electric energy) and thermal energy (with preliminary converting it by a heat converter into direct current electric energy), while converting the resulting total energy electrical energy consistently high quality current.

The ability to sum light energy with other types of energy is achieved due to the fact that in the proposed device in the upper part of the housing is installed a photovoltaic converter, to which an additional single-phase excitation winding of the pathogen is connected. Light energy is converted by a photoelectric converter, to which an additional single-phase excitation winding of the pathogen is connected, into direct current electric energy. The direct current flowing through the additional single-phase excitation winding of the pathogen creates a magnetic flux, which, according to the superposition law, is summed with the magnetic flux created by the main excitation winding of the pathogen, respectively providing a summation of the torques created by the currents flowing in the main and additional single-phase excitation windings.

The ability to summarize thermal energy with other types of energy is achieved due to the fact that in the proposed device in the lower part of the housing a thermal converter is installed, which is configured to be connected to an additional multiphase winding through the control unit. Thermal energy is converted by a heat converter, to which an additional multiphase winding is connected, into direct current electric energy. The control unit provides the appropriate phase switching of the additional multiphase winding so that the magnetic flux induced by the currents flowing in the phases generates a torque that coincides in direction with the torque created by an external source of mechanical energy.

The ability to summarize mechanical energy with other types of energy is achieved due to the fact that in the proposed device on the rotor shaft outside the housing, a magnetic gearbox is installed, consisting of a magnetic gearbox shaft, drive and driven drives made of non-magnetic material, and permanent magnets, placed on the master and slave disks with opposite poles towards each other, while the master disk is rigidly fixed to the shaft of the magnetic gearbox, and the driven disk is rigidly fixed to the shaft rotor of a three-input axial generator set. The mechanical energy of rotation (torque) is supplied from an external source (for example, wind) to the shaft of the magnetic gearbox, through the magnetic gearbox it is transmitted to the rotor shaft of the three-input axial generator set. In the node “additional multiphase winding - axial permanent multipolar magnet of the exciter exciter with permanent magnets of rotor position sensors mounted on it”, the torque coming from an external source of mechanical energy is summed up with the torque created from the heat source coming from an external source. When the rotor of the three-input axial generator set rotates under the action of the total torque, the resulting total mechanical energy is converted in the node "axial permanent axial multipolar magnet of the exciter exciter - multiphase winding of the exciter exciter" into electrical energy. In the node “main and additional single-phase excitation windings of the pathogen - multiphase winding of the pathogen armature”, the electric energy obtained from the conversion of mechanical and thermal energy is summed up with the electric energy received from the conversion of light energy.

Improving the reliability of the electric machine is achieved due to the fact that in the proposed device, electricity is obtained from the simultaneous conversion of energy from three heterogeneous sources. In this case, a three-input axial generator set generates electric energy even in the absence of light energy, and in case of insufficient heat energy, an external backup energy source can be used - a rechargeable battery connected to the power supply unit with a differential-minimum relay of the control unit. In addition, an additional single-phase excitation winding of the pathogen can be connected to an external photoelectric converter, and an additional multiphase winding can be connected via a control unit to an external heat converter. This allows you to increase the reliability of incoming light and heat signals, as well as their power, which accordingly allows to increase the reliability and power of the installation as a whole.

In FIG. 1 shows a general view of the proposed three-input axial generator set; FIG. 2 is an electrical diagram of the proposed three-input axial generator set; FIG. 3 is an electrical diagram of a control unit; FIG. 4 is a graph of voltages at the output of pulse forming units.

The three-input axial generator set (TAGU) contains: a housing 1, in which a control unit 20 is installed, rotor position sensors 24 (DPR), each of which has a signal winding 25 and an excitation winding (not shown in Fig. 1-4), lateral axial magnetic circuit 10 with multiphase winding 11 of the armature of the main generator, side axial magnetic circuit 21 with additional multiphase winding 22, internal axial magnetic circuit 3 with multiphase winding 4 of the arm exciter, main 5 and additional 6 single-phase and exciter windings, and a rotor, on the shaft 12 of which, through the disks 15 and 16, a permanent axial multipolar magnet 2 of the exciter inductor and an axial rotating magnetic circuit 7 with a multiphase winding 8 of the armature of the exciter and a single-phase excitation winding 9 of the main generator are rigidly fixed to the shaft 12, while a constant axial multipolar the magnetizer inductor 2 magnet is made with permanent magnets 23 of the rotor position mounted on it along the outer radius, and the case of the DPR 24 with the signal winding 25 and the windings th excitation (FIG. not shown) is installed on the line of intersection of the plane passing through the axis of symmetry of the permanent magnets 23 of the rotor position and perpendicular to the axis of rotation of the rotor, with each DPR 24 mounted on the inner surface of the housing 1 by means of a rod 26 and equidistant from neighboring DPR 24, and the rotor shaft 12 is fixed in the bearing units 13 and 14, is closed by a cover 55 on one side and extends beyond the housing 1 on the other hand, while the single-phase excitation winding 9 of the main generator is connected to the multiphase winding 8 of the exciter armature single-phase two-half-wave rectifier 18, the main single-phase excitation coil 5 of the pathogen is connected to the multi-phase winding 4 of the exciter armature through the multi-phase two-half-wave rectifier 17, and the multi-phase winding 11 of the armature of the main generator is connected to the output multi-phase two-half-wave rectifier with the external power supply 19, which is made the battery (AB) 40. In the upper part of the housing 1 is installed a photoelectric converter (PEC) 32, made with POSSIBILITY connect to additional single-phase excitation winding of the exciter 6, which is adapted to connect to an external photoelectric converter (FIG. not shown) through contacts 56 (FIG. 2). In the lower part of the housing 1, a thermal converter (TP) 33 is installed, made with the possibility of connecting to an additional multiphase winding 22 through the control unit (BU) 20, and at the end of the rotor shaft 12 extending outside the housing 1, a magnetic gearbox 27 is installed, consisting of the shaft 34 of the magnetic gearbox, the drive 28 and the driven 29 drives made of non-magnetic material, and the permanent magnets 30 and 31 placed on the drive 28 and the driven 29 drives with opposite poles facing each other, while the drive drive 28 is rigidly fixed to the shaft 34 of the magnetic gearbox 27, the driven disk 29 is rigidly fixed to the shaft 12 of the TAGU rotor. An additional multiphase winding 22 is made with the possibility of connecting through the control unit 20 to an external thermal converter (ETC) 57 (Fig. 2).

BU 20 (Fig. 3) contains a differential-minimum relay (DMR) 38, a power supply unit (BP) 39, configured to connect via DMR 38 to TP 33, an external thermal converter (HTP) 57, or to an external backup power source - AB 40 and having outputs of high level (VU) and low level (NU) (Fig. 3) voltage, pulse forming units (FI) "A" 35, FI "B" 36 and FI "C" 37, one for each phase ( A, B and C, respectively) of an additional multiphase winding 22.

The low level (NU) BP 39 ensures the operation of electronic components of the circuit, in particular transistors and DPR 24; a high level (VU) makes it possible to obtain a large current in the additional multiphase winding 22, during which a magnetic flux occurs, which participates in the creation of a rotating electromagnetic moment, which drives the TAGU rotor.

The backup power supply of the BU 20 is carried out from the AB 40 ((Fig. 2, 3) (it is not part of the BU 20).

Each of the blocks FI “A” 35, FI “B” 36 and FI “C” 37 of the control unit 20 (Fig. 3) contains the first 49 (R1), second 50 (R2), third 51 (R3), fourth 52 ( R4) and the fifth 53 (R5) limiting resistors, the first and second control transistors 41 (VT6) and 42 (VT7), the first and second pairs of switching transistors 45 (VT2) and 46 (VT3) - the first pair, 47 (VT1) and 48 (VT4) - the second pair, and two transistors 43 (VT5) and 44 (VT8), forming the logical element "NOT" 54.

The logical element "NOT" 54 of each block FI "A" 35, FI "B" 36 and FI "C" 37 through the fifth limiting resistor 53 (R5) is connected to the low-level output (NU) BP 39, and its input and base of the first control transistor 41 (VT6) connected to the signal winding 25 of the DPR 24, while the base of the second control transistor 42 (VT7) is connected to the output of the logical element "NOT" 54, and the collectors of the first 41 (VT6) and second 42 (VT7) control transistors through the first and the third limiting resistors 49 (R1), 51 (R3), respectively, are connected to the low-level (NU) output of the PSU 39, when The emitters of the first 41 (VT6) and second 42 (VT7) control transistors are grounded, and the bases of each pair of switching transistors are interconnected: the base of the switching transistor 45 (VT2) with the base of the switching transistor 46 (VT3) is the first pair, the base of the switching transistor 47 (VT1) with the base of the switching transistor 48 (VT4) - the second pair, while the bases of the first pair of switching transistors 45 (VT2) and 46 (VT3) are connected to the collector of the first control transistor 41 (VT6), and the bases of the second pair of switching transistors 47 ( VT1) and 48 (VT4) are connected to the collector the second control transistor 42 (VT7), while the collectors of the switching transistors, one from each pair (transistor 45 (VT2) from the first pair and transistor 47 (VT1) from the second pair) are connected to the high-level (VU) output of the power supply 39, and their emitters through the second and fourth limiting resistors 50 (R2) and 52 (R4), respectively, are connected to the corresponding terminals of the corresponding phase (for block FI “A” 35: the emitter of the switching transistor 45 (VT2) of the first pair is connected through the fourth limiting resistor 52 (R4) to the beginning of phase A, and the emitter the switching transistor 47 (VT1) of the second pair through the second limiting resistor 50 (R2) is connected to the end X of phase A) of the additional multiphase winding 22 and to the collectors of the switching transistors of the other pair (the emitter of the switching transistor 45 (VT2) of the first pair through the fourth limiting resistor 52 ( R4) is connected to the collector of the switching transistor 48 (VT4) of the second pair, the emitter of the switching transistor 47 (VT1) of the second pair through the second limiting resistor 50 (R2) is connected to the collector of the switching transistor 46 (VT3) of the first pair )

TAGU works as follows. The TAGU rotor is driven into rotation from an external source of mechanical energy (input of mechanical energy) through a magnetic gear 27. In addition, the rotor is driven into rotation when an electromagnetic torque arises from the conversion of thermal energy into electrical energy.

When the shaft 34 of the rotor of the magnetic gearbox 27 is mounted with a drive disk 28 with a permanent magnet 30 mounted on it due to the force interaction of the permanent magnets 30 and 31, caused by their tendency to be pulled by opposite poles, a torque is created that is transmitted to the shaft 12 of the TAG rotor, causing rotation permanent axial multipolar magnet 2 exciters inductor and axial rotating magnetic circuit 7 with multiphase winding 8 of the armature of the pathogen and single-phase winding 9 of the excitation of the main generator pa

Moreover, if the voltage at the output of the TP 33 (or at the output of the VTP 57 when it is connected) is higher than the voltage of the AB 40 by 1 V, then the DMR 38 connects the output of the TP 33 (or, respectively, the output of the VTP 57) (TAGU thermal input) to the power supply unit 39 control 20 (Fig. 3).

In this case, from the power supply unit 39 to the field winding (not shown in the diagrams), the DPR 24 is supplied with a low level direct current (NI) voltage (Fig. 3). As a result of the current flowing in the excitation winding of the DPR 24 around the signal windings 25 in the case of the DPR 24, a magnetic flux arises, which creates a transverse magnetic field, and the signal windings 25 become sensitive to the magnetic flux generated by the permanent magnets 23 of the rotor position (Fig. 1, 2, Fig. 3 is not shown). During rotation of the permanent axial multipolar magnet 2 of the exciter inductor with the permanent magnets 23 of the rotor position attached to it, the magnetic flux generated by these magnets interacts with the transverse magnetic field created by the DPR excitation windings 24, in which the signal windings 25 are located. As a result of this interaction, the signal windings 25 a low level DC voltage is generated, and the voltage at the output of the signal windings 25 occurs when there are permanent position magnets 23 I rotor near the signal windings 25 both when the rotor of the TAGU is stationary, and when it rotates. The signals from the output of the signal windings 25 of each DPR 24 are fed to the input of the corresponding unit FI “A” 35, FI “B” 36 and FI “C” 37.

When applying pulses from blocks FI “A” 35, FI “B” 36 and FI “C” 37 BU 20 to the corresponding phases of the additional multiphase winding 22, the magnetic flux generated by the additional multiphase winding 22 interacts with the magnetic flux generated by a permanent axial multipolar magnet 2 exciters inducers, giving the rotor TAGU (permanent axial multi-pole magnet 2 exciters inducers and an axial rotating magnetic circuit 7 with a multiphase winding 8 of the armature of the pathogen and a single-phase winding 9 of the main excitation generator of) additional torque which is directed in accordance with the rotation torque of the mechanical power source and is added to it.

If the voltage at the output of the TP 33 (or at the output of the VTP 57 when it is connected) becomes lower than the voltage of the AB 40 by 1 V, then the DMR 38 switches the BP 39 to the AB 40. In this case, the formation of signals at the inputs of the blocks FI “A” 35, FI “ In "36 and FI" S "37 is carried out in the same way as when connecting the BP 39 through DMR 38 to TP 33 (or to the ECP 57, respectively).

When the permanent axial multipolar magnet 2 of the exciter exciter rotates and the axial rotating magnetic circuit 7 with the multiphase winding 8 of the exciter armature and the single-phase excitation coil 9 of the main generator rotate, the magnetic flux of the constant axial multipolar magnet 2 of the exciter inductor interacts with the multiphase winding of the exciters of the internal subbench 4 of the sub-exciter armor 3, rigidly installed in the housing 1, and induces a multiphase EMF system in it, which rectifies I multiphase full-wave rectifier 17 and fed to a single-phase main exciter field winding 5, arranged in the axial grooves in the inner yoke 3. In this case, the primary winding 5 of a single-phase excitation creates a magnetic flux of agent.

At the same time, in a photomultiplier 32 (and in an external photomultiplier (not shown in Fig. 1-3)) (light input), light energy is converted to direct current electric energy. The exciter flowing through the additional single-phase excitation winding 6 connected to the PEC 32 (and / or to the external PEC when it is connected to it through pin 56) (Fig. 2), the direct current creates a magnetic flux, co-directional with the magnetic flux generated by the main single-phase winding 5 excitations of the pathogen.

The total magnetic flux created by the main 5 and additional 6 single-phase excitation windings of the pathogen interacts with the multiphase winding 8 of the exciter armature, laid in the slots of the internal axial rotating magnetic circuit 7, and induces a multiphase EMF system in it, which is rectified by the multiphase two-half-wave rectifier 18 and fed to the single-phase winding 9 excitation of the main generator, laid in the grooves of the internal axial magnetic circuit 7.

The magnetic flux of a single-phase excitation winding 9 of the main generator interacts with the multiphase winding 11 of the armature of the main generator, laid in the grooves of the lateral axial magnetic circuit 10, and induces a multiphase EMF system in it, which is rectified by the output multiphase two-half-wave rectifier 19 and is supplied to the network and to AB 40 for it charging.

Permanent magnets 23 of the rotor position, fixed along the outer radius of the permanent axial multi-pole magnet 2 of the exciter inductor, serve to generate control signals in each of the blocks FI “A” 35, FI “B” 36 and FI “C” 37. The polarity of all permanent magnets 23 exciter exciter is the same. The number of permanent magnets 23 of the rotor position and their location is selected so that when they act on the signal winding 25 of the DPR 24, control signals appear that, when the permanent axial multipolar magnet 2 of the exciter inductor with permanent magnets 23 of the rotor position rotates, would ensure timely switching of the current flow direction in the corresponding phases of the additional multiphase winding 22 to continuously create the desired electromagnetic torque and give p torus rotation in a predetermined direction.

Blocks FI "A" 35, FI "B" 36 and FI "C" 37 are identical in composition. Therefore, we consider the operation of only one block, for example, FI “A” 35, implying that the blocks FI “B” 36 and FI “C” 37 work in a similar way.

Upon receipt of a control signal from the signal winding 25 DPR 24 to the input of the first control transistor 41 (VT6) (at the moment of passage of the permanent magnets 23 of the rotor position past the signal winding 25 DPR 24, which corresponds to the phase of the additional multiphase winding 22, which is connected to the considered unit FI “A "35) it opens, the switching transistors 45 (VT2) and 46 (VT3) of the first pair are closed.

In the logic element “NOT” 54, the transistor 43 (VT5) is closed, the transistor 44 (VT8) is opened, the voltage corresponding to the logic “O” is generated at the output of the logic element “NOT” 54, while the second control transistor 42 (VT7) is closed, and switching transistors 47 (VT1) and 48 (VT4) of the second pair open.

In this case, the current flows from the high-level output (VU) of the BP 39 through the open switching transistor 47 (VT1), the second limiting resistor 50 (R2), through the corresponding phase (phase "A" for the block FI "A" 35) of the additional multiphase winding 22 , through an open switching transistor 48 (VT4) to ground. Moreover, the magnetic flux generated by the current in the corresponding phase (phase “A” for the FI unit “A” 35) of the additional multiphase winding 22 acts on the poles of the same polarity of the permanent axial multipolar magnet 2 of the exciter inductor.

In the absence of a control signal from the signal winding 25 (at the time of a pause between the passage of one of the permanent magnets 23 of the rotor position past the signal winding 25 of the ДПР 24, corresponding to the phase of the additional multiphase winding 22, which is connected to the considered unit FI "A" 35), the first control transistor 41 (VT6) is closed, the switching transistors 45 (VT2) and 46 (VT3) of the first pair are opened.

In the logic element "NOT" 54, the transistor 43 (VT5) opens, the transistor 44 (VT8) closes, the output of the logic element "NOT" 54 produces a voltage corresponding to the logical "1", while the second control transistor 42 (VT7) opens, and switching transistors 47 (VT1) and 48 (VT4) of the second pair are closed.

In this case, the current flows from the high-level output (VU) of the BP 39 through the open switching transistor 45 (VT2), the fourth limiting resistor 52 (R4), through the corresponding phase (phase “A” for the block FI “A” 35) of the additional multiphase winding 22 through an open switching transistor 46 (VT3) to ground. Moreover, the magnetic flux generated by the current in the corresponding phase (phase “A” for the FI unit “A” 35) of the additional multiphase winding 22 affects the poles of a different polarity of the permanent axial multipolar magnet 2 of the exciter inductor.

The formation of a signal at the output of each of the blocks FI “A” 35, FI “B” 36 and FI “C” 37 that occurs when the TAGU rotor rotates (that is, when the permanent magnets 23 pass the rotor position past the signal winding 25 of the DPR 24, corresponding to the phase of the additional multiphase winding 22, which is connected to the considered unit FI “A” 35, FI “B” 36 and FI “C” 37, respectively), is shown in FIG. four.

Thus, in the proposed three-input axial generator set, by means of electromagnetic conversion, the mechanical, thermal and light energies supplied to the corresponding TAGU inputs from three dissimilar energy sources are summed up, while the resulting total energy is converted to high-quality direct current electric energy.

Claims (4)

1. Three-input axial generator set, comprising a housing in which a control unit is installed, rotor position sensors, a signal winding and an excitation winding, a lateral axial magnetic circuit with a multiphase winding of the armature of the main generator, a lateral axial magnetic circuit with an additional multiphase winding, are installed in each of the housings, an internal axial magnetic circuit with a multiphase winding of the exciter armature, the main and additional single-phase excitation windings of the pathogen, and a rotor, and the shaft of which by means of disks is fixedly fixed with a permanent axial multipolar magnet of the exciter exciter and an axial rotating magnetic circuit with a multiphase winding of the exciter armature and a single-phase excitation winding of the main generator, while the permanent axial multipolar magnet of the exciter is made with constant rotor position magnets that are external to it and the housing of the rotor position sensor with a signal winding and an excitation winding is installed on the line a plane passing through the axis of symmetry of the permanent magnets of the rotor position and perpendicular to the axis of rotation of the rotor, with each rotor position sensor mounted on the inner surface of the housing by means of a rod and equidistant from neighboring rotor position sensors, and the rotor shaft mounted in the bearing assemblies, closed by a cover with one side and goes beyond the housing on the other hand, while the single-phase excitation winding of the main generator is connected to the multiphase winding of the exciter armature through the multiphase motor a half-wave rectifier, the main single-phase excitation winding of the pathogen is connected to the multiphase winding of the exciter armature through a multiphase two-half-wave rectifier, and the multiphase winding of the armature of the main generator is connected to the output multiphase two-half-wave rectifier, characterized in that a photoelectric converter is installed in the upper part of the additional excitation the pathogen, which is configured to connect to an external photocell to the transducer, a heat converter is installed in the lower part of the casing, made with the possibility of connecting to an additional multiphase winding through the control unit, and at the end of the rotor shaft extending outside the casing, a magnetic gearbox is installed, consisting of a shaft of a magnetic gearbox, drive and driven drives made of non-magnetic material, and permanent magnets placed on the master and slave disks with opposite poles towards each other, while the master disk is rigidly fixed to the shaft netic gearbox, drive plate rigidly fixed to the rotor shaft trehvhodovoy axial genset, and output the multi-phase full-wave rectifier is configured to connect to an external backup power source - rechargeable battery, wherein more multi-phase winding is configured to connect via the control unit to an external heat transducer. 2. The three-input axial generator set according to claim 1, characterized in that the control unit comprises a differential-minimum relay, a power supply unit configured to connect by means of the differential-minimum relay to a heat converter, to an external heat converter, or to an external backup energy source - battery - and having outputs of high level and low voltage level, and pulse forming units, one for each phase of the additional multiphase winding. 3. The three-input axial generator set according to claim 2, characterized in that each of the pulse generating units comprises first, second, third, fourth and fifth limiting resistors, first and second control transistors, the first and second pairs of switching transistors and two transistors forming logical element "NOT". 4. The three-input axial generator set according to claim 3, characterized in that the logical element “NOT” of each pulse forming unit is connected to the low-level output of the power supply unit through the fifth limiting resistor, and its input and the base of the first control transistor are connected to the signal winding of the rotor position sensor while the base of the second control transistor is connected to the output of the logic element "NOT", and the collectors of the first and second control transistors through the first and third limiting resistors in are connected to the low-level output of the power supply, while the emitters of the first and second control transistors are grounded, and the bases of each pair of switching transistors are interconnected, while the bases of the first pair of switching transistors are connected to the collector of the first control transistor, and the bases of the second pair of switching transistors are connected to the collector the second control transistor, while the collectors of the switching transistors, one of each pair are connected to the high-level output of the power supply, and their emi the tters through the second and fourth limiting resistors are connected to the corresponding terminals of the corresponding phase of the additional multiphase winding and to the collectors of the switching transistors of the other pair.

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