RU81609U1 - STABLE AC VOLTAGE GENERATION SYSTEM - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used in the design of power sources based on mechanoelectric generation systems designed for aviation needs. An unregulated magnetoelectric generator 1 is driven into rotation by the shaft of an aircraft engine 2 with a variable speed of rotation, in proportion to which the frequency and voltage at the generator output change. Electricity consumers 7 are designed for a stable AC voltage of an unstable frequency. Stabilization of the output voltage of the generator is carried out by loading it with a reactive current generated by an adjustable source of reactive current 4. The magnitude of the reactive current is determined by the magnitude of the control signal from the output of the comparison unit 3 of the generator output voltage and the set one. If the output voltage of the generator 1 exceeds a predetermined level, the reactive current is formed lagging behind it in phase, and in the case of a decrease - leading. The technical result, which consists in simplifying the design, increasing reliability and improving the overall dimensions, is achieved through the use of a relatively simple in design adjustable reactive current source 4 with a semiconductor switch, as well as by reducing the dimensions of the generator itself, mounted directly on the shaft of the aircraft engine. 1 s.p. f-ly, 5 ill.

Description

The utility model relates to the field of electrical engineering and can be used in the design of power sources based on mechanoelectric generation systems used in aircraft construction.

Known aviation systems for generating voltage of variable frequency, containing unregulated generators with excitation from permanent magnets associated with the shaft of the aircraft engine directly. The outputs of the generators are connected to the load via semiconductor converters. Generators generate an AC voltage of an unstable frequency at their outputs, and its converters convert it to a stable AC voltage of a stable frequency (2). A disadvantage of the known devices is the increased mass-dimensional characteristics due to the fact that the entire power of the generator, including the load, is converted in the converter. In addition, these systems have a relatively low power factor and high manufacturing complexity.

Closest to the utility model is a system for generating a stable AC voltage of an unstable frequency, in which the generator shaft is directly connected to the aircraft engine shaft. The output voltage is stabilized by regulating the current in the field windings of the generator (3). A disadvantage of the known device is the complexity of the design of the generator, consisting of three stages with a rotating rectifier. The complexity of the design entails a decrease in reliability and a deterioration in mass and overall performance. In addition, the system has a low quality transient, which can lead to the appearance of overvoltages at the output of the generator and, consequently, a decrease in reliability.

The technical result that can be achieved using the utility model is to simplify the design, increase reliability and improve overall dimensions.

The technical result is achieved due to the fact that in the system for generating a stable AC voltage, containing connected to the output of the aircraft engine magnetoelectric generator with excitation from permanent magnets, the output terminals of which

designed to connect the consumer with a stable voltage of variable frequency, connected to one of the inputs of the comparison node, the second input of which is connected to the source of the specified voltage, and the outputs of the comparison node are connected to the regulation input of the reactive current source, the output terminals of which are connected parallel to the output terminals of the generator or to its additional windings, the reactive current source is configured to generate a proportional value of the output signal of the reactive comparison node oh current, outpacing the output voltage of the generator when it decreases relative to a given or lagging in phase from the output voltage of the generator when it rises relative to a given. In addition, the reactive current source may include inductors connected to the outputs of the semiconductor switch with a power factor that varies according to the input signal, and the input of regulation of the reactive current source is the input of the switch, and the output is the free leads of the inductors.

Figure 1 presents a structural diagram of the device.

Figures 2 and 3 show embodiments of a reactive current source.

Figure 4 presents an option for connecting a reactive current source to additional generator windings.

Figure 5 shows a diagram of the operation of the device.

The system for generating a stable AC voltage (Fig. 1) contains a generator 1 with permanent magnet excitation connected to the output of the aircraft engine 2. The output terminals of the generator, designed to connect the consumer with a stable voltage of variable frequency, are connected to one of the inputs of the comparison unit 3. Second input the comparison node is connected to a source of a given (reference) voltage with an output signal U back. The outputs of the comparison node 3 are connected to the control input of the reactive current source 4, the output terminals of which are connected parallel to the output terminals of the generator 1 or to its additional windings 5. The reactive current source includes inductors connected to the outputs of the semiconductor switch 6 with a power factor that is changed according to the input signal . The input of regulation of the reactive current source 4 is the input of the switch 6, and the output is the free leads of the chokes. The reactive current source 4 provides the formation of a proportional value of the output signal of the reactive current comparison unit, outpacing the output voltage of the generator when it decreases relative to a given voltage, and lagging in phase from the output voltage of the generator when it rises relative to a given. Figure 2 and 3 presents embodiments of a reactive current source with various modifications of the semiconductor switch 6.

Figure 2 shows the switch on incompletely controlled devices (thyristors), designed for single-zone regulation of reactive current with lagging Cos φ. Figure 3 presents the switch, made on fully controllable keys (transistors), performing two-zone regulation of the output voltage of the generator. Two-zone regulation is ensured by the formation of an additional reactive current generator loading the current circuits with leading Cos φ (to increase the output voltage of the generator) and with lagging Cos φ (to reduce the output voltage).

The switch 6 (Figure 2) in its simplest form consists of three pairs of on-board thyristors that control the current of the chokes connected to the corresponding phases of the generator. The role of reactors can be performed by the inductance of the generator windings and the inductance (Llin.) Of the communication line between the generator and the load 7.

To smooth the ripples created by the switch, filter 8 can be included between the output terminals of the generator and the load.

Figure 4 presents an option for connecting a reactive current source to additional generator windings. This modification can be recommended to increase efficiency, as the currents through the keys of the switch 6 will be reduced to the same extent as the voltage of the additional winding 5 will exceed the voltage on the main windings of the generator.

The device operates as follows.

An unregulated magnetoelectric generator 1 is driven into rotation by the shaft of an aircraft engine 2 with a variable speed of rotation, in proportion to which the frequency and voltage at the generator output change. Electricity consumers 7 are designed for a stable AC voltage of an unstable frequency. The output voltage of the generator is stabilized by loading it with a reactive current generated by an adjustable source of reactive current 4. The magnitude of the reactive current is determined by the magnitude of the control signal (current) coming from the output of the comparison unit 3 of the generator output voltage and a given (reference). The comparison process can be carried out in an analogue way, digitally or in their modification.

Figure 5 shows a diagram of the operation of the device, where:

9 is a natural external characteristic of a synchronous generator at a nominal speed with Cos φ = 1;

10 - external characteristic of the generator when the demagnetization current lags behind the voltage with Cos φ <1 (lagging Cos φ at the rated speed);

11 - external characteristic of the generator at an advancing bias current with Cos φ <1 (leading Cos φ);

A is the point corresponding to the rated load (9);

In - the point of intersection of the external characteristics of the generator (10) at the demagnetization current (Cos φ lagging) with direct rated voltage;

C is the point of intersection of the external characteristic (11) with the leading bias current (leading Cos φ) from the direct rated voltage.

Ikz - short circuit point.

In accordance with the static external characteristic (9), the generator is in a state determined by the operating point A, which corresponds to the rated load (Unom .; Inom.) At nominal speed.

When the generator load increases, for example, by ΔI ₂ , the generator voltage decreases by ΔU ₂ , and the operating point moves accordingly to point D of curve (9).

To maintain the rated voltage at the output of the generator 1 at a current of I ₂ , the generator must be magnetized, i.e. provide the corresponding leading Cos φ to move the working point D to point C on the external characteristic (11).

If the generator load is reduced to a value determined by the current I ₁ , i.e. by ΔI ₁ , the voltage of the generator increases by ΔU ₁ , which corresponds to point E on the external characteristic (9).

To reduce the voltage in this case, it is necessary to demagnetize generator 1, providing it with a lagging Cos φ, as a result of which the operating point from position E will move to V (curve 10), providing a stable value of the nominal output voltage of the generator.

“Leading Cos φ” is equivalent to the capacitive nature of the reactive current, phase-ahead of the output voltage of the generator, and “Lagging Cos φ” to the inductive nature of the reactive current, phase-behind the output voltage of the generator.

If you maintain the output voltage at a nominal level at minimum speed and maximum load, i.e. to ensure a mode of operation in which, with all changes in the load and revolutions, the voltage of the generator will increase, then only one-zone voltage regulation by the demagnetization current with lagging Cos φ is possible.

If you maintain the output voltage at a nominal level at maximum speed and minimum load, i.e. to ensure a mode of operation in which, with all changes in the load and revolutions of the generator voltage decreases, then only one-zone regulation of the bias current with leading Cos φ is possible.

Thus, the utility model allows to significantly simplify the design, increase reliability and improve the overall dimensions of the generation system with complete energy conversion. This result was achieved through the use of a relatively simple in design adjustable source of reactive current with

semiconductor switch. The improvement of the mass-dimensional parameters was also achieved by reducing the dimensions of the generator itself, mounted directly on the shaft of the aircraft engine.

Optimum mass-dimensional characteristics of the device with high reliability allow it to be recommended when designing systems for generating stable AC voltage in a wide range of their use.

Sources of information taken into account when compiling the description:

"Electrical equipment of aircraft", ed. S.A. Gruzkova, vol. 1 Moscow, MPEI, 2005 p. 430-435; p. 243, 434.

Claims (2)

1. A system for generating a stable AC voltage, comprising a magnetoelectric generator connected to the output of the aircraft engine with excitation from permanent magnets, the output terminals of which are designed to connect a consumer of a stable voltage of variable frequency, connected to one of the inputs of the comparison node, the second input of which is connected to a source of a given voltage, and the outputs of the comparison node are connected to the control input of the reactive current source, the output terminals of which are connected parallel to the output terminals of the generator or to its additional windings, while the reactive current source is configured to generate a proportional value of the output signal of the reactive current comparison node, outpacing the output voltage of the generator when it decreases relative to a given or phase-behind the output voltage of the generator when it rises relative to given. 2. The system for generating a stable AC voltage according to claim 1, characterized in that the reactive current source includes reactors connected to the outputs of the semiconductor switch with a power factor that is changed according to the input signal, the control input of the reactive current source being the input of the switch, and the output - free conclusions of throttles.