RU177678U1 - Autonomous power supply system with electric start of the power plant - Google Patents

Abstract

The device relates to electrical engineering and to pulsed power electronics and is intended for use as an autonomous power supply system for transport and stationary electrical complexes, in particular, fully electrified aircraft. The main technical result of the proposal is to expand the system’s functionality by stabilizing the amplitude of the AC voltage without reducing the coefficient power and efficiency of the system. Additional results include increased reliability and reduced system noise due to the exclusion of circuits for unauthorized "through currents" when exposed to electromagnetic pulses of lightning and by providing "soft" switching of electronic keys. These results are ensured by the fact that in the proposed power supply system containing a power plant 1, magnetoelectric starter-generator with permanent magnets 2 on the rotor and anchor winding 3 on the stator, contactor 4, switchgear your 5 alternating voltage with unstable parameters, ballast inductive-capacitive filter 6, differential filter rack 7-8 with terminals 9-10-11, bridge reversible rectifier-inverter converter, consisting of three two-arm electronic-key racks 12-13, 14- 15 and 16-17 with reverse diodes 18-19, 20-21 and 22-23, as well as a control unit 24 with 25.26 feedback circuits and with pulse-modulator leads 27, an alternating voltage switchgear 28 with a stable amplitude was introduced, auxiliary inductive capacitive filter 29, as well as three bidirectional electronic keys 30, each electronic key of the converter is equipped with a chain consisting of a damper choke 31, a snubber capacitor 32, a two-diode rack 33-34 and a discharge electronic key 35, and the control unit is equipped with relay-pulse terminals 36. On the drawing also shows the emergency release 37 of the joint shaft of the power plant.

Description

The device relates to electrical engineering and to pulsed power electronics and is intended for use as an autonomous power supply system for transport and stationary electrical complexes, in particular, fully electrified aircraft.

A well-known autonomous power supply system with electric start of the power plant (analogue), containing DC switchboards of low and high voltage alternating current of stable and variable frequency (115 V, 400 Hz; 220 V, 50 Hz; 115 V, 360 ... 720 Hz). All generation channels are interconnected by energy converters based on inverter racks with MOSFET modules. Electric start is carried out by connecting an external source of electricity to any of the distribution devices (for example: 220 V, 50 Hz; ± 270 V; 115 V, 400 Hz; 27 V). (Electric aircraft: concept and technology / A.V. Levin, S.M. Musin, S.A. Kharitonov, K.L. Kovalev, A.A. Gerasin, S.P. Khalyutin: edited by S.M. Mukhina: Ufa State Aviation Technical University - UFA: USATU. 2014 .-- 388 p., P. 129, Fig. 3.37).

The disadvantages of this autonomous power supply system with the electric start of the power plant include: excessive mutual redundancy of each of the main power supply and electric start channels, requiring a large number of static inverter-rectifier converters and, as a result, the large mass and dimensions of the system as a whole.

Of the known devices, the closest in technical essence to the proposed system is an autonomous power supply system with an electric start of the power plant (prototype), comprising: a power plant with a drive shaft, a magnetoelectric starter-generator with permanent magnets on the rotor and a three-phase armature winding on the stator connected through a contactor to an alternating voltage switchgear with unstable parameters, three-phase ballast inductive-capacitive filter, differential two-condensation The filter rack Thorne, reversible bridge inverter rectifier converter consisting of the three-phase electronic key racks reverse diode, and a control unit. (F.R. Ismagilov, M.A. Kiselev, V.E. Vavilov, N.G. Tarasov (FSBEI HE Ufa State Aviation Technical University, Ufa, 12 Karl Marx St., 12).

The disadvantages of this autonomous power supply system with electric start-up of the power plant (prototype) include: narrow system capabilities due to the inability to stabilize the amplitude of the AC voltage without reducing the power factor and efficiency of the system, low reliability and large noise emissions of the system due to the presence of unauthorized "overcurrents" circuits when exposed to electromagnetic pulses of lightning and due to the “hard” switching of electronic keys (with simultaneous surges of currents and voltages).

The main technical result of the proposal is to expand the functionality of the system by providing stabilization of the amplitude of the AC voltage without reducing the power factor and efficiency of the system. Additional results include increased reliability and reduced system noise due to the exclusion of circuits for unauthorized "through currents" when exposed to lightning electromagnetic pulses and by providing "soft" switching of electronic keys.

These results are ensured due to the fact that in the proposed power supply system containing a power plant, a magnetoelectric starter-generator with permanent magnets on the rotor and an armature winding on the stator, a contactor, an AC switchgear with unstable parameters, a ballast inductance-capacitive filter, a differential filter rack , bridge reversible rectifier-inverter converter, consisting of three two-arm electronic-key racks with reverse di odes, as well as a control unit with feedback circuits and with pulse-modulator outputs, an alternating voltage switchgear with a stable amplitude, an auxiliary inductive-capacitive filter, as well as three bidirectional electronic keys, each electronic converter key is equipped with a circuit consisting of a damper inductor , a snubber capacitor, a two-diode rack and a discharge electronic key, and the control unit is equipped with relay-pulse outputs. The drawing also shows the emergency release joint shaft of the power plant.

Experimental studies of the laboratory layout and computer modeling of the proposed power supply system confirm its efficiency and the feasibility of wide industrial use.

The drawing (Fig. 1) shows a schematic power diagram and control channels of the proposed autonomous power supply system with electric start of the power plant.

In FIG. 2 is a schematic diagram of a control unit.

The proposed autonomous power supply system with an electric start of the power plant contains: a power plant 1 with a drive shaft, a magnetoelectric starter-generator with permanent magnets 2 on the rotor and a three-phase anchor winding 3 on the stator connected through a contactor 4 to an AC switchgear 5 with unstable parameters, three-phase ballast inductive-capacitive filter 6, differential two-condenser filter rack 7-8 with grounded middle and bipolar extreme conclusions 9-10-11, a bridge reversible rectifier-inverter converter, consisting of three phase two-arm electronic-key racks 12-13, 14-15 and 16-17, shunted by reverse diodes 18-19, 20-21 and 22-23. The system also contains a control unit 24 (Fig. 2) with feedback circuits 25, 26 for external currents and voltages with pulse-modulator outputs 27. In addition, the system includes: an alternating voltage switchgear 28 with a stable amplitude, a three-phase auxiliary inductive-capacitive filter 29, as well as three bidirectional electronic keys 30. Each electronic key of the bridge rectifier-inverter converter is equipped with a damping-snubber circuit consisting of a damper choke 31, included in series with this key, a snubber capacitor 32, a two-diode rack 33-34, and a bit electronic key 35. The control unit is also provided with pulse-relay terminals 36.

Phase two-arm electronic-key racks 12-13, 14-15 and 16-17 are connected by their inter-arm middle leads through a ballast inductive-capacitive filter 6 and contactor 4 to the armature winding 3 of the starter-generator, and with their DC outputs to the extreme terminals of the filter racks 7-8. An auxiliary inductive-capacitive filter 29 is connected between the inter-shoulder middle terminals of the electronic-key racks of the bridge rectifier-inverter converter and the variable voltage switchgear 28 with a stable amplitude. Bidirectional electronic keys 30 ground the indicated inter-arm outputs of the bridge transducer.

Each of the bit electronic keys 35 through a two-diode rack 33-34 is connected to the first power output of this key, through the first diode of the rack and the snubber capacitor 32 to the second power output of this key and is directly connected to the corresponding AC switchgear 5 with unstable parameters.

The control unit 24 with its pulse-modulator terminals 27 is connected to the control terminals of the keys 12 to 17 of the bridge rectifier-inverter converter, and its relay-signal leads 36 to the control terminals of the bi-directional electronic keys 30.

Key transistors or two-operational (lockable for control) thyristors can be used as electronic keys from 12 to 17 and 30, and key transistors as bit electronic keys 35.

The drawing also shows the emergency release 37 of the joint of the shaft of the power plant 1 (for example, shear or movable key) to protect against overloads and short circuits.

Autonomous power supply system with electric start of the power plant operates as follows.

A supercapacitor or / and a storage battery is connected to the terminals 9-10-11 of the filter rack 7-8. Switchgears 5 and 28 of alternating voltages connect the loads (consumers) of an alternating three-phase (or single-phase) current with unstable parameters and a stable voltage amplitude, respectively.

On the pulse-modulator terminals 27 and relay-signal terminals 36 of the control unit 24, high-frequency rectangular pulse-width modulated and short-term pulses are formed, respectively, for controlling electronic keys.

The power supply system can operate in two modes:

1) power plant start-up mode (starter mode) and 2) power supply mode (loads) of consumers from the magnetoelectric generator through switchgears 5 and 28 and through a recharged storage battery (with a filter rack 7-8). Let's consider these modes one by one.

1. The electric start mode of the power plant (starter mode).

In this mode, the bridge reversible rectifier-inverter converter (with keys 12-17 and 30) performs the function of an adjustable three-phase voltage inverter, linearly increasing in frequency and amplitude from zero to maximum values (as the rotor 2 of the starter-generator, operating in synchronous mode, accelerates electric motor). In this case, the phase currents in the armature winding 3 may have a rectangular shape ("meander" - with or without intermediate pauses). The operation of the specified bridge inverter is widely covered in the literature and does not require additional explanation.

The specified mode continues until there is sufficient promotion of the shaft of the power plant 1, starting from which the power plant switches to independent operation (“low gas mode”) and is capable of carrying a generator load.

2. The power supply mode of consumers (loads) of alternating and rectified currents.

In this mode, the bridge reversible rectifier-inverter converter performs the function of the so-called Vienne rectifier with the correction of the power consumption coefficient. The specified correction is carried out using pulse-width regulation of phase currents in the armature windings 3 of the starter-generator with ensuring their sinusoidal shape with synchronism and common mode with the corresponding phase voltages. This allows (unlike the prototype) to simultaneously provide: a) stabilization of the rectified voltages (on the filter rack 7-8) with the approach of the coefficient of power consumption to unity, i.e. with minimal heat loss in the AC circuits, and b) stabilization of the voltage amplitude at the switchgear 28 by supplying the input terminals of the auxiliary inductive-capacitive filter 29 from the filter rack 7-8 through alternately unlocked rectifier diodes 18 to 23.

In both considered modes, firstly, with the help of damping chokes 31, the “through overcurrents” are eliminated due to unauthorized switching on of power switches (from 12 to 17 and 30) when 24 control lightning electromagnetic pulses are exposed to the control unit, and secondly, “Soft” switching of power switches (without simultaneous surges of currents and voltages in the circuit of the switches), thereby reducing switching heat losses and noise emissions. In this case, the snubber capacitors 32 are completely discharged into the circuit of the corresponding inductor of the inductive-capacitive filter 6 through the discharge electronic key 35, diode 18, the inductor 31 and the key 12 (and through other similar circuits), and the energy stored by the snubber capacitors is transferred to the load with low heat loss.

Thus, in comparison with the prototype in the proposed autonomous power supply system with electric start of the power plant, the main technical result is provided: expanding the system’s functionality by stabilizing the amplitude of the AC voltage without reducing the power consumption coefficient and system efficiency, as well as additional results: increasing reliability and lowering system interference due to the exclusion of circuits for unauthorized "through overcurrents" when exposed to electric electromagnetic pulses of lightning and by providing "soft" switching electronic keys.

Claims (2)

1. Autonomous power supply system with electric start of the power plant, comprising a power plant with a drive shaft, a magnetoelectric starter-generator with permanent magnets on the rotor and a three-phase armature winding on the stator, connected through a contactor to an alternating voltage switchgear with unstable parameters, a three-phase inductive-capacitive ballast filter, differential two-condenser filter rack with grounded middle and bipolar extreme leads, bridge reversible The first rectifier-inverter converter, consisting of three phase two-arm electronic key racks, shunted by reverse diodes and connected with their inter-shoulder middle leads through a ballast inductive-capacitive filter and contactor to the armature winding of the starter generator, and with its direct current leads to the extreme terminals of the filter racks, as well as a control unit with feedback circuits for currents and voltages and with pulse-modulator outputs connected to the control terminals of the electronic-key device a bridge converter, characterized in that an alternating current distributor with a stable amplitude, a three-phase auxiliary inductive-capacitive filter inserted between the inter-arm middle outputs of the electronic key racks of the bridge rectifier-inverter converter and said switchgear, as well as three bidirectional electronic keys are inserted into it . 2. An autonomous power supply system with an electric start of the power plant according to claim 1, characterized in that each electronic key of the bridge converter is equipped with a snubber-snubber chain consisting of a damper choke connected in series with this key, a snubber capacitor, a two-diode rack and a discharge electronic key, and the control unit is equipped with relay-pulse outputs connected to the control terminals of the discharge electronic keys, each of which is connected through a two-diode rack to the first the main output of this key, through the first diode of the rack and through the snubber capacitor, to the second power output of this key and is directly connected to the corresponding AC voltage switchgear with unstable parameters.

Images