RU45059U1 - DC / AC CONVERTER - Google Patents

Abstract

The utility model relates to electrical engineering, namely to direct current energy converters at the input to the energy of an alternating multiphase current at the output, in particular, into two or three phase alternating voltages, shifted together by any programmed angles, then DS / AC. It is preferable to use in light-engine aviation (LA), where there is only 12 or 24 V from the batteries on board, and a three-phase alternating voltage of 36 V 400 Hz, the phases of which are shifted by 120 °, is required to power the gyroscope (horizon).

The technical task of the utility model is to increase the quality of the conversion, namely, increasing the conversion efficiency and obtaining a quasi-sinusoidal form of the converted voltage of 36 V 400 Hz.

For this purpose, a DS / AC converter is proposed, comprising a DC power source at the input and three busbars of an AC three-phase voltage source of energy at the output, characterized in that it contains the first and second DS / DS, a PWM controller, the first, second and third operational amplifiers (ОУ), the first, second and third power amplifiers with the following connections: a DC power source is connected to the inputs of the first and second DS / DS, the output of the first DS is connected to the power input of the PWM controller, the output of the second DS / DS is connected to the input E power first, second and third op-amp and the first, second and third power amplifiers; the first, second and third outputs of the PWM controller are connected to the inputs of the first, second and third op-amps, respectively, and the high-frequency output of the PWM controller is connected to the control input of the second DS / DS; the outputs of the first, second and third op-amps are connected to the inputs of the first, second and third power amplifiers, respectively, the outputs of which are the outputs of the converter.

Description

The utility model relates to electrical engineering, namely to direct current energy converters at the input to the energy of an alternating multiphase current at the output, in particular, into two or three phase alternating voltages, shifted together by any programmed angles, then DS / AC. It is preferable to use in light-engine aviation (LA), where there is only 12 or 24 V from the batteries on board, and a three-phase alternating voltage of 36 V 400 Hz, the phases of which are shifted by 120 °, is required to power the gyroscope (horizon).

Currently, the aircraft has become widespread throughout the world, so in the United States and Canada the total number of light private aircraft reaches several hundred thousand. In the Russian Federation, this type of aviation also began to develop successfully. It should be noted that even light-engine aircraft are very expensive, more expensive than prestigious cars, so developers and manufacturers save on what is possible, including on instrumentation; in the foreseeable future, aircraft are unlikely to become cheaper. Therefore, in the lightest class of aircraft (for 2-5 people), as well as in sports airplanes, a minimum of aerobatic and other equipment is set, so no horizons (AG) are set, which automatically provides for flights only in conditions of direct line of sight to the ground. Hence the decrease in aircraft electrical equipment: special current generators are not placed on the shaft of aircraft engines: three-phase alternating voltage 36 V 400 Hz or 115 V 1000 Hz, without which it is impossible to power AG gyromotors. This situation is acceptable and possible for areas in which a large number of sunny days per year: Central Asia, the North Caucasus, southern Ukraine, but for most regions of the Russian Federation: North, Urals, Siberia and the Far East is unacceptable, because more time of the year, non-AH aircraft will be fun,

but you have to fly. But the conduct and resolution of flights are determined by the “Airworthiness Standards”, which regulate the “minimum weather”, i.e. under what weather conditions a particular type of aircraft can fly. Of course, for planes without AG, flying in clouds, at night, in fog is strictly prohibited. Therefore, the use of AG on such aircraft powered from a direct current network with conversion (reception) into a 3-phase alternating voltage of 36 V 400 Hz, which slightly increases the cost of the aircraft, but does not require the installation of additional expensive alternating voltage generators, which is also must be placed on the shaft of the engine of the aircraft, which requires its completion, take power from it, then you need to lay an additional feeder on the dashboard, then the question of flight safety (planning) When an engine failure, etc.

Known converters of DC voltage +27 V to 3-phase AC 36 V 400 Hz, type PT-250 or PT-500, see "Technical description PT-250 and PT-500", M, Mechanical Engineering, 1972

The disadvantages of these converters are:

- high overall mass characteristics (GMH), weight up to 10 kg with an output power of 250 W;

- the complexity and unreliability of the electrical circuit, because they are electromechanical type.

Therefore, their installation on light aircraft is absolutely unacceptable.

At the current level of electronics, it is much easier to put a DC-to-AC converter for powering the AG.

Known converter, see. Radio, No. 7, 2000, pp. 37-38, in which a 3-phase alternating voltage is obtained by sequentially connecting the capacitance and the inductor to the single-phase voltage, to the midpoint of which and to their extreme points are connected the motor windings connected by a triangle.

This device is rated at ~ 220 V / 50 Hz, but it can easily be counted at 36 V / 400 Hz.

Its disadvantages include: first you need to get the primary alternating single-phase voltage, which requires certain costs, then the stability of the phase shift can be better, especially when the ambient temperature changes from -40 to + 60 ° C, which can lead to failure of the gyromotor AG, or at least to a loss in the number of revolutions, and consequently to a blockage of the AG gyroscope during airplane evolutions.

A generator-shaper is known, essentially a DS / AC converter that converts direct current energy into alternating current energy of 36 V 400 Hz, see. Radio, No. 1, 1999, pp. 54-55, in which a three-phase sequence of pulses with accurate and constant phasing is formed, which controls the key stages on transistors, and those, in turn, the motor windings are PROTOTYPE.

The disadvantages of the prototype include:

- a large error in maintaining the frequency due to the use of an RC chain in the master oscillator, especially when the ambient temperature changes over a wide range from minus -60 ° С to + 60 ° С (as in aviation);

- the shape of the alternating voltage is rectangular with a duty cycle = 2, and this shape leads to low efficiency and most importantly to overheating of the gyromotor electric motor, which in some cases is simply unacceptable, because on these engines, the distortion of the shape of the 3-phase voltage should not exceed 8%, and with a rectangular voltage, the distortion reaches 30%.

The technical task of the utility model is to increase the quality of the conversion, namely, increasing the conversion efficiency and obtaining a quasi-sinusoidal form of the converted voltage of 36 V 400 Hz.

For this purpose, a DS / AC converter is proposed that contains a DC power source at the input and three buses of an AC power source

three-phase output voltage, characterized in that it contains the first and second DS / DS, PWM controller, the first, second and third operational amplifiers (op amps), the first, second and third power amplifiers with the following connections: a DC power source is connected to the inputs the first and second DS / DS, the output of the first DS is connected to the power input of the PWM controller, the output of the second DS / DS is connected to the power inputs of the first, second and third op-amps and the first, second and third power amplifiers; the first, second and third outputs of the PWM controller are connected to the inputs of the first, second and third op-amps, respectively, and the high-frequency output of the PWM controller is connected to the control input of the second DS / DS; the outputs of the first, second and third op-amps are connected to the inputs of the first, second and third power amplifiers, respectively, the outputs of which are the outputs of the converter; the RF voltage output from the PWM controller has two buses, the voltages of which are 180 ° phase-shifted to each other; at the input of each operational amplifier is an integrating chain; each power amplifier is made on the transistors of the plus and minus arms, respectively, with the transistors of each arm connected in cascade and the common output point of the power amplifier through an RC parallel circuit by a feedback bus connected to the input of its operating an amplifier; each operational amplifier is turned on according to a large-scale inverting circuit.

Figure 1 shows the structural diagram of the Converter, figure 2, 3 and 4 - schematic diagrams of its nodes, which depict: 1 - the first DC to DC Converter (DC / DC), 2 - the second DC / DC, 3 - PWM controller, 4, 5, and 6 are the first, second, and third operational amplifiers (op amps), respectively, 7, 8, and 9 are the first, second, and third power amplifiers (AM), respectively, the +12 V input bus and 3- output buses x phase voltage 36 V 400 Hz.

The converter has the following connections.

The DC power source is connected to the inputs of the first and second DS / DS 1 and 2, the output of the first DS 1 is connected to the power input of the PWM controller 3, the output of the second DS / DS 2 is connected to the power inputs of the first, second and third op amps 4, 5, 6 and the first, second and third power amplifiers 7, 8, 9; the first, second and third outputs of the PWM controller 3 are connected to the inputs of the first, second and third op-amps 4, 5, 6, respectively, and the high-frequency output of the PWM controller 3 is connected to the control input of the second DS / DS 2; the outputs of the first, second and third op-amps 4, 5, 6 are connected to the inputs of the first, second, and third power amplifiers 7, 8, 9, respectively, the outputs of which are the outputs of the converter.

The converter can be made on the following electro-radio elements. The first DS / DS is on the 142 Series IMS, see the Reference. Integrated Circuits, M, RadioSoft, 2001, pp. 477-450. The second DS / DS is a miniature switching power supply boosting - of its own design. PWM controller - on the Motorola IC MSP 430F14XIPM, see Russian server. Motorola Semiconductor Component Sectors www.motro.ru. The first, second and third operational amplifiers are based on the IC 140UD17, see the Handbook. Integrated Circuits, M, RadioSoft, 2001, p. 43. The first, second and third power amplifiers on transistors 2T825 and 2T826, see the Reference. Semiconductor devices, M, P and S, 1994, p. 214 and 71, respectively.

Converter DS / AC works as follows. When you turn on the voltage +12 V to the input of the first and second DS / DS 1 and 2, the first DS / DS converts the voltage +12 V to +3.3 V on the voltage regulator DA2 (figure 2) to power the PWM controller 3, which while it begins to generate pulse sequences f and 40 kHz, shifted between themselves by 180 ° in phase. These sequences go to the second ДС / ДС 2, where they control the power field-effect transistors VD1 and VD2, switching them with a frequency of 40 kHz, these transistors together with a step-up transformer U1,

+12 V power supply and secondary windings with rectifier diodes and filters form a switching power supply. The voltages ± 18 V obtained at the second DS / DS are supplied to the power buses of the first, second, and third operational amplifiers and power amplifiers. The PWM controller 3 generates at its outputs four-Hz pulse sequences of 400 Hz A, 400 Hz B and 400 Hz C, which are digital-to-analog PWM sequences. Each sequence goes to its operational amplifier: 400 Hz A to the first op-amp, 400 Hz B to the second op-amp, 400 Hz C to the third op-amp. At the inputs of these op-amps are integrating circuits R1, C1 (Fig. 4), at the outputs of which we have pure sinusoidal voltages, these received voltages are amplified by the indicated operational amplifiers and swing power amplifiers 7, 8 and 9, respectively, to a voltage of 36 V. Negative feedback with the output of each power amplifier to the inverse input of its op-amp serves to increase the stability of the output stages.

Claims (5)

1. The DS / AC Converter containing a DC power source at the input and three buses of an AC three-phase voltage source of energy at the output, characterized in that it contains the first and second DS / DS, PWM controller, the first, second and third operational amplifiers (OA ), the first, second and third power amplifiers with the following connections: a DC power source is connected to the inputs of the first and second DS / DS, the output of the first DS is connected to the power input of the PWM controller, the output of the second DS / DS is connected to the power inputs of the first, second the second and third op-amps and the first, second, and third power amplifiers; the first, second and third outputs of the PWM controller are connected to the inputs of the first, second and third op-amps, respectively, and the high-frequency output of the PWM controller is connected to the control input of the second DS / DS; the outputs of the first, second and third op-amps are connected to the inputs of the first, second and third power amplifiers, respectively, the outputs of which are the outputs of the converter. 2. The DS / AC converter according to claim 1, characterized in that the RF voltage output from the PWM controller has two buses, the voltages of which are 180 ° phase-shifted to each other. 3. The DS / AC converter according to claim 1, characterized in that at the input of each operational amplifier there is an integrating chain. 4. The DS / AC converter according to claim 1, characterized in that each power amplifier is made on the transistors of the plus and minus arms, respectively, with the transistors of each arm connected in cascade and a common output the point of each power amplifier through an RC parallel circuit feedback bus connected to the input of its operational amplifier. 5. The DS / AC converter according to claim 1, characterized in that each operational amplifier is turned on according to a large-scale inverting circuit.