RU2666903C1 - Autonomous ac power plant - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to the electric power industry, namely to autonomous AC power plants based on internal combustion engines and a synchronous generator, and is designed to generate electricity of stable frequency and stable voltage at a variable frequency of the engine shaft rotation. Problem to be solved is the creation of a highly efficient autonomous AC power plant. In a self-contained AC power plant comprising a series of interconnected ICEs of variable speed, a synchronous generator, a two-link frequency converter configured as blocks: a controlled rectifier, a capacitor bank and a voltage inverter, a current sensor to which the load power calculation unit is connected, the output of which is connected to the unit for setting the economical speed of the shaft of the internal combustion engine, raising the transformer and output terminals, between the step-up transformer and the output terminals there is a two-link frequency converter, made in the form of blocks: an uncontrolled rectifier, a capacitor bank and a voltage inverter.

EFFECT: technical result of the proposed invention is a reduction in the weight and dimensions of an autonomous power plant.

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Description

The invention relates to the electric power industry, namely to autonomous AC power plants based on the internal combustion engine and synchronous generator, and is intended to generate electricity of a stable frequency and a stable voltage at a variable speed of the internal combustion engine shaft.

A device for generating AC voltage, made on the basis of the internal combustion engine and synchronous generator, in which the stabilization of the frequency of the alternating voltage of the stator of the synchronous generator is provided by stabilization of the rotational speed of the ICE shaft, and the stabilization of the voltage amplitude of the stator of the synchronous generator by changing the current of the excitation winding [P.A. The bourgeoisie. Automation of ship electric power systems. L., Shipbuilding, 1970, p. 156-162]. The disadvantage of this device is its low efficiency (high fuel consumption) due to the fact that the internal combustion engine operates at a constant speed at different loads.

The closest in technical solution is a device for generating electrical energy of alternating voltage (RF Patent No. 2412513 for the invention. IPC Н02J 3/34, 2011), containing a series-connected ICE of variable speed with a unit for generating the optimal speed of the ICE shaft connected to it made in the form of blocks: setting the economical speed of the internal combustion engine shaft, the signal adder, the internal combustion engine speed sensor and the internal combustion engine shaft speed controller, synchronous generator, two-link conversion A frequency converter made in the form of blocks: a controlled rectifier, a capacitor bank, a voltage inverter, a current sensor, to which a load power calculation unit is connected, the output of which is connected to the unit for setting the economical speed of the internal combustion engine shaft, raising the transformer and output terminals. The stabilization of the frequency and amplitude of the output voltage in this device is carried out at the level of nominal values for a synchronous generator, provided that the fuel consumption of the internal combustion engine included in the generator unit is minimized by selecting the optimal shaft speed when the load power changes from zero to the nominal value.

The disadvantage of this device is that it includes a step-up transformer operating at a frequency equal to the frequency of the output voltage (usually 50 Hz), and therefore having significant mass-dimensional indicators.

The task at hand is the creation of a highly efficient autonomous AC power station.

The technical result of the invention is to reduce the overall dimensions of an autonomous power plant.

This technical result is achieved by the fact that in an autonomous power plant of alternating current containing a series-connected ICE of variable speed, a synchronous generator, a two-link frequency converter, made in the form of blocks: a controlled rectifier, a capacitor bank and a voltage inverter, a current sensor to which a calculation unit is connected load power, the output of which is connected to the unit for setting the economical speed of the internal combustion engine shaft, increasing the transformer and output terminals, between increasing t a transformer and output terminals have a two-link frequency converter, made in the form of blocks: an uncontrolled rectifier, a capacitor bank and a voltage inverter.

The installation between the step-up transformer and the output terminals of a two-link frequency converter, made in the form of blocks: an uncontrolled rectifier, a capacitor bank and a voltage inverter, distinguishes the proposed device from the known one, as it allows the step-up transformer to be made high-frequency (nominal frequency - 20-30 kHz), which significantly reduces the overall dimensions of the installation.

The invention is illustrated in FIG. 1, which shows a functional diagram of the device.

Autonomous AC power station contains a series-connected ICE 1, a synchronous generator 2, a two-link frequency converter 3, made in the form of blocks: a controlled rectifier 4, a capacitor bank 5 and a voltage inverter 6, a current sensor 7, a step-up transformer 8, a two-link frequency converter 9, made in the form of blocks: an uncontrolled rectifier 10, a capacitor bank 11 and a voltage inverter 12, output terminals 13. To the internal combustion engine 1 is connected a speed controller 14 of the shaft speed of the internal combustion engine 1, the frequency sensor 15 is rotated ICE shaft 1, signal combiner 16, included in the block 17 for generating the optimal speed of the ICE shaft 1. This also includes the unit 18 for setting the economical speed of the ICE shaft 1. The excitation block 19 of the synchronous generator 2 with the power supply leads 20 is connected to the synchronous excitation winding generator 2, with the outputs of the unit 18 for setting an economical engine speed of the engine 1. The voltage stabilization unit 21, consisting of a voltage adjuster 22, a signal combiner 23 and a voltage regulator 24, is connected to the output of the voltage sensor 25, with which the excitation unit 19 of the synchronous generator 2 is also connected. The input of the unit 18 is connected to the load power calculation unit 26. The outputs of the sets 27 and 28 of the frequency of the output voltage are connected respectively with voltage inverters 6 and 12.

The device operates as follows.

The block 17 for generating the optimal rotational speed of the engine ICE shaft 1 receives a signal from the load power calculation unit 26, which is connected to the outputs of the voltage sensor 25 and current sensor 7, which respectively measure the voltage and current at the output of the two-link frequency converter 3. Depending on the value of the load power, the unit 18 setting the economical speed of the engine ICE shaft 1, the program of work of which contains the optimal dependences of the engine ICM 1 speed on the load power, corresponding to the minimum fuel consumption, sets the optimum the total frequency of rotation of the ICE shaft 1. Using the signal adder 16, the difference between the signal for setting the optimal engine speed of the ICE 1 from unit 18 and the signal of the sensor 15 of the ICE shaft speed 1 is calculated. The signal from the adder 16 is fed to the input of the speed controller 14 of the ICE shaft 1, which maintains the rotational speed of the ICE shaft 1 at the level set by unit 18. Thus, when the load power changes at the output terminals 13, and therefore on the ICE shaft 1, the rotational speed of the ICE shaft 1 will be kept optimal from the point of view of minimum consumption of fuel.

Since the rotational speed of the ICE shaft 1 will vary depending on the load power, the amplitude and frequency of the alternating voltage of the synchronous generator 2 will also vary depending on the load power.

The stabilization of the amplitude of the alternating voltage at the output terminals 13 at the level of the nominal value for the synchronous generator 2 is as follows.

The controlled rectifier 4, which is part of the frequency converter 3, converts the alternating voltage of the stator of the synchronous generator 2 into a constant voltage of a given value. The output voltage of the controlled rectifier 4 is stabilized at a predetermined level using the voltage stabilization unit 21, which includes the voltage regulator 24, the input of which is connected to the signal adder 23, the inputs of which receive signals from the voltage regulator 22 and from the voltage sensor 25. For to smooth the output voltage of the controlled rectifier 4, a capacitor bank 5 is included at its output, which is also necessary for the operation of the voltage inverter 6, which is part of a two-link converter ovatelya frequency 3. In addition, the capacitor bank is 5 compensates for energy storage and energy peaks and dips in the dynamic mode. The output voltage of the controlled rectifier 4 is converted using an inverter 6 into an alternating voltage of a sinusoidal shape, the amplitude of which is equal to the constant voltage at the output of the controlled rectifier 4.

When the load power changes from zero to the nominal value, the rotational speed of the ICE shaft 1, and, consequently, the voltage amplitude of the synchronous generator 2 will vary over a wide range.

In this case, the output voltage of the controlled rectifier 4 will vary over a wide range and will be less than the rated voltage of the stator of the synchronous generator 2. To increase the output voltage at the output terminals 13 to the level of the rated voltage of the synchronous generator 2 at the output of the voltage inverter 6 (behind the current sensor 7) is turned on step-up transformer 8. Setting the output voltage of the controlled rectifier 4, equal to the ratio of the amplitude of the nominal voltage synchronous generator 2 to the transformation coefficient of step-up transformer 8, at the output of step-up transformer 8 we get an alternating three-phase voltage, the amplitude of which is equal to the nominal value for synchronous generator 2.

The frequency of the output voltage of the inverter 6 in the proposed installation is set by the control unit 27 of the frequency of the output voltage high, as a rule, at a level of 20-30 kHz. Moreover, as a step-up transformer 8, a high-frequency transformer is used, the overall dimensions of which are many times smaller than the transformer operating at a low frequency (tens of Hz) used in the prototype (RF Patent No. 2412513 for the invention. IPC Н02J 3/34, 2011) . The output voltage of the step-up transformer 8 is rectified using an uncontrolled rectifier 10, which is part of a two-link frequency converter 9. To smooth the output voltage of the uncontrolled rectifier 10, a capacitor bank 11 is included at its output, which is also necessary for the operation of the voltage inverter 12. The output voltage of the uncontrolled rectifier 10 is converted using a voltage inverter 12, which is part of the frequency Converter 9, in an alternating voltage sinusoidal shape, the amplitude of torogo equal to the DC voltage at the output of an uncontrolled rectifier 10.

The frequency of the output three-phase voltage at the output terminals 13 is maintained stable with the help of the inverter 12 at the level set by the unit of the frequency adjuster 28 of the output voltage.

The excitation unit 19 of the synchronous generator 2, receiving power through the terminals 20 of the power supply, generates a current in the excitation winding of the synchronous generator 2, taking into account the signal from the unit 18 for setting the economical speed of the internal combustion engine shaft 1 and from the voltage sensor 25.

Thus, when changing the rotational speed of the ICE shaft 1 at the output terminals 13, the amplitude of the alternating three-phase voltage is maintained at the level of the nominal value for the stator of the synchronous generator 2.

Moreover, due to the fact that the step-up transformer operates at a high frequency (20-30 kHz), its overall dimensions and installation are generally reduced, despite the fact that additional elements are introduced into the circuit: an uncontrolled rectifier, a capacitor bank and a voltage inverter.

The patent has the development, according to which a two-link frequency converter 3, consisting of a controlled rectifier 4, a capacitor bank 5 and a voltage inverter 6, and a two-link frequency converter 9, consisting of an uncontrolled rectifier 10, a capacitor bank 11 and a voltage inverter 12, can be made form of direct frequency converters.

Replacing two-link frequency converters with direct frequency converters allows you to switch from a two-stage conversion of electricity to a single-stage one, and thus increase the efficiency of a power plant (reduce specific fuel consumption), and also further reduce its overall dimensions.

According to the scientific, technical and patent literature, the authors are not aware of the claimed combination of features aimed at achieving the task, and this solution does not follow clearly from the prior art, which allows us to conclude that the solution corresponds to the level of the invention.

Claims (1)

An autonomous AC power plant containing a variable-speed internal combustion engine connected in series with an optimal engine speed generating unit connected to it, a synchronous generator, a two-link frequency converter made in the form of blocks: a controlled rectifier, a capacitor bank and a voltage inverter, a current sensor to which connected to the load power calculation unit, the output of which is connected to the unit for setting the economical speed of the internal combustion engine shaft, raising the transformer and output dnye conclusions, characterized in that between the step-up transformer and the output terminals installed two-tier inverter arranged in blocks: uncontrolled rectifier, capacitor bank voltage and the inverter; a two-link frequency converter, consisting of a controlled rectifier, a capacitor bank and a voltage inverter, and a two-link frequency converter, consisting of an uncontrolled rectifier, a capacitor bank and a voltage inverter, are made in the form of direct frequency converters.

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