HU209227B - Iverter, in particular for safety power supply system - Google Patents

Abstract

Field of the Invention The present invention relates to an inverter converter, in particular to security power supply systems, which has a high-frequency, symmetric rectangular-voltage inverter (2) connected to a direct-current accumulator, preferably a rechargeable battery (1) or a battery-operated accumulator, connected to a high-frequency transformer (3). The essence of the invention is that - the output of the high-frequency transformer (3) is connected to a power input of a high-frequency pulse-width modulated, parallel-controlled current controller (4), and - with a half-life offset control factor (4) shifted to the control input of the controlled-current transformer (4) a pulse width modulating control unit (8) suitable for emitting a signal δ, 0.5-δ), and a control signal input (9) of the control unit (8) is connected to the control signal input (8) of the inverter (2), while a controlled current controller ( 4) power output is connected to the input of a high frequency filter (6) with a sinusoidal network frequency output. 14 ----- L _ -. . .------------------- - - - - - - - - - Figure 1 EN 209 227 BA Description: 6 pages ( within this 2 page chart)

Description

The essence of the invention is that

- the output of the high frequency transformer (3) is connected to the power input of a high frequency, pulse width modulated parallel controlled current controller (4), and

- a connected pulse width modulating control unit (8) capable of delivering a signal with an opposite output ratio (δ, 0.5-δ) shifted by a half-period, controlled by the current controller (4), and

- the carrier frequency signal output (9) of the control unit (8) is connected to the control signal input of the inverter (2),

- the power output of the controlled current controller (4) is connected to the input of a high frequency filter (6) having a sinusoidal network frequency output.

---- L _ -. . .------------------ first figure

HU 209 227 B

Description: 6 pages (including 2 pages)

HU 209 227 Β

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a converter, particularly to a security power supply system, comprising a high frequency, symmetrical rectangular voltage inverter with an output connected to a DC storage, preferably a rechargeable battery or a battery pack.

As is known, the security systems used in practice consist of a battery pack, an inverter connected to its output, and a transformer connected to the output of the inverter, the output of the transformer being connected to the output of the security power system through a filter.

AC power consumers requiring a secure power supply are powered from the output terminals by the battery pack. The inverter converts the DC voltage to a stabilized AC voltage. Voltage control is accomplished by 50 Hz or high frequency (eg 20 kHz) sinusoidal pulse width modulation, but in both cases power transmission, voltage matching and galvanic isolation are performed by a 50 Hz network transformer. In the former case, the filter for generating a sinusoidal output voltage is 50 Hz, in the latter a high-frequency filter (20 kHz).

A battery charger to maintain battery power generally consists of a 50 Hz mains adapter transformer, a controlled rectifier, and a filter smoothing choke. In addition to the battery pack, the size and weight of the unit are primarily those of 50 Hz transformers and transformers. filters.

Advanced security power systems utilize high frequency and / or carrier frequency power transmission, in most cases combined with modulation techniques.

For example, patent application HU 189141 discloses a solution in which amplitude modulation is used to form the carrier frequency and the output voltage shape of the energy transfer. However, at high performance, this is extremely costly and therefore uneconomic.

A solution is known, for example, from patent application HU 186360. Here, energy is transmitted by high frequency and pulse width modulation. In this embodiment, the carrier frequency is significantly lower than the power transmission frequency. The disadvantage is that the size of the inductive and capacitive filter elements cannot be reduced to the same extent as that of the energy transfer transformer, and that the control procedure is more complicated than when the energy transfer frequency and the carrier frequency are equal. In addition, energy transfer transformers must also have energy storage capability.

It is an object of the present invention to provide a solution which reduces the weight and size of the equipment, thereby making the equipment designed by it more economical and widening in scope.

The present invention is based on the discovery that low-frequency sinusoidal signals can be formed from rectangular high-frequency signals using the classical-sinusoidal network-frequency parallel-controlled rectification principle, by applying a semiconductor-offset, at the same frequency as the power transmission frequency. The latter has a dual advantage. On the one hand, the transmission of energy at higher frequencies and on the other hand the practical implementation of pulse width modulation becomes easier. In this way, for example, converting the energy of a DC voltage storage device (battery) into a rectangular high-frequency signal by small inductive elements (transformer, filter, etc.) can produce a 50 Hz AC power supply.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high-frequency, symmetric rectangular-voltage inverter with an output to a DC converter, particularly to a security power supply system, which is connected to a DC voltage storage device, preferably a rechargeable battery or a battery pack. The essence of the invention is that

- the output of the high-frequency transformer is connected to the input of a high-frequency, pulse-width modulated, parallel-controlled current-controlling power, and

- a pulsed width modulating control unit capable of transmitting a signal with a semiconductor offset output of opposite semiconductor input to the controlled current controller input, and

- the inverter control signal input is connected to the control unit carrier frequency signal output,

- the output of the controlled current controller is connected to the input of a high-pass filter with a sinusoidal mains frequency output.

According to an embodiment of the invention, the control unit has two pulse width modulators of the same structure, which have a common encoded control signal input, a common frequency control signal input and a common clock input, and a clock input connected to a fourth input of one pulse width modulator forming one of the control outputs of the control unit, while the output of one pulse width modulator is connected to the fourth input of the other pulse width modulator on the one hand and the output of the control unit carrier signal and the other pulse width modulator output to the other control output of the control unit.

According to another embodiment of the invention, the power input of the current controller comprises a bridge switching input of electronic switching elements, the outputs of which are connected via an inductance to one of the terminals of the frequency converter of the converter,

EN 209 227 Β while the other terminal of the frequency converter output of the converter is connected to the center terminal of the transformer.

According to a further embodiment of the invention, the control unit has a two-wire control output controlled by one of the output coefficients on the two wires and the control input of the third electronic switching element, while the control unit has another two-wire and another the output of the controller is connected to the control input of the second electronic switching element in the bridge circuit and to the control input of the fourth electronic switching element.

In a preferred embodiment, the electronic switching elements are thyristors or transistors (e.g., MOSFETs or IGBTs) and diodes connected in series with the transistors.

The invention will be explained in more detail with reference to the embodiments shown in the drawings, Fig. 1 illustrates an inverter according to an embodiment of the invention, and Fig. 2 shows an embodiment of a high frequency parallel controlled current controller and filter.

The output terminals of the DC storage device of FIG. 1 are preferably connected to the input of an inverter 2 having a symmetrical rectangular voltage. The output of inverter 2 is connected to the power input 5 of a high frequency countercurrent controlled current controller 4 via a high frequency transformer 3. The output of the current controller 4 is connected to a high-frequency filter 6 and the output of the filter 6 is a sine-shaped network frequency output 7 of the converter.

The output signal 9 of the carrier frequency pulse width modulating control unit 8 for converter control is connected to the control signal input of the inverter 2, while the control outputs 10, 11 of the pulse width modulating control unit 8 are connected to the current control terminal input 4.

The control unit 8 has two pulse width modulators 12, 13 of the same construction. The design of pulse width modulators 12, 13 is described, for example, in U.S. Patent Application Serial No. 193,736. The pulse width modulators 12, 13 have a common encoded control signal input 14, a common frequency control signal input 15 and a common clock 16 input. The clock input 16 of the control unit 8 is connected via a frequency divider 17 to the fourth input of one of the pulse width modulators 12 and forms one of the control outputs 10 of the control unit 8 connected to the current controller 4. The output of the other pulse width modulator 13 is the other control output 11 of the control unit 8. The output of one pulse width modulator 12 is connected, on the one hand, to the fourth input of the other pulse width modulator 13 and, on the other hand, forms the output of the carrier frequency signal 9 connected to the inverter 2 of the control unit.

Fig. 2 shows an embodiment of the current controller 4 and the filter 6, where the inductances required for both units are solved by a common element (s). The two terminals of the transformer 3 are connected to a bridge switch consisting of electronic switching elements 18, 19, 20, 21, which is the power input 5 of the current controller 4, while the outputs of the bridge switch are connected via a , while the other terminal of the mains frequency output is the center terminal of the transformer 3. The filter capacitor 24 of the filter 6 is connected between the two terminals of the network frequency output 7.

The control output 10 of the control unit 8 is connected to the control input 10a of the first electronic switching element 18 in the current controller 4 and the control input 10b of the third electronic switching element 20, while the control output 8 of the control unit 8 is also connected to the second electronic switching element 19a. connected to the control input and to the control input 11b of the fourth electronic switching element 21. The control inputs 10a, 10b are controlled by 0.5 to δ with one output factor, and a half-period offset between them, while the control inputs 11a, 11b are controlled by another output factor with also a half-period offset. The other output factor δ can vary from 0 to 0.5.

The electronic switching elements 18, 19, 20, 21 may be, for example, fast thyristors or transistors (MOSFETs, IGBTs) and diodes connected in series with them.

In the operation of the circuit arrangement according to the invention, the sine form of the output voltage is set by modulating the modulating frequency and / or the modulating code according to a sine function. This is done by varying the control factor, by modulation of the pulse width according to the invention.

Claims (5)

PATENT CLAIMS 1. A direct current converter, in particular for a security power supply system, comprising a high frequency, symmetrical rectangular voltage inverter with an output connected to a direct current storage device, preferably a rechargeable battery or accumulator, in a converter, - the output of the high frequency transformer (3) is connected to the power input of a high frequency, pulse width modulated parallel controlled current controller (4), and - a connected pulse width modulating control unit (8) capable of delivering a signal with an opposite output ratio (δ, 0.5-δ) shifted by a half-period, controlled by the current controller (4), and - a controller for the control signal input of the inverter (2) GB 209 227 Β unit (8) carrier frequency signal output (9) connected while - the power output of the controlled current controller (4) is connected to the input of a high frequency filter (6) having a sinusoidal network frequency output, Converter according to Claim 1, characterized in that the control unit (8) has two pulse width modulators (12, 13) of the same structure, which have a common coded control signal input (14), a common frequency control signal input (15) and a common frequency control signal input (15). a clock input (16), the clock input (16) being connected via a frequency divider (17) to a fourth input of one of the pulse width modulators (12) and forming a control output (10) of the control unit (8); the output of the pulse width modulator (12) is connected to the fourth input of the second pulse width modulator (13) and forms the carrier frequency signal output (9) of the control unit (8) while the output of the other pulse width modulator (13) 11) is formed. A converter according to claim 1 or 2, characterized in that the power input (5) of the current controller (4) is made of electronic switching elements (18). 19,20,21), which are connected via one inductance (22,23) to one terminal of the frequency converter output (7) of the converter and the other to the frequency converter output (7) of the converter terminals of the transformer (3). A converter according to claim 3, characterized in that the control output (10) of the control unit (8) is a two-wire control unit with an output factor (0.5-δ) on the two wires and the first electronic switching element (18) in the bridge circuit. connected to the control input (10a) and the control input (10b) of the third electronic switching element (20), while the other control output (11) of the control unit (8) is controlled by a second electronic switching element (19) ) is connected to the control input (11a) and to the control input (11b) of the fourth electronic switching element (21). Converter according to claim 3 or 4, characterized in that the electronic switching elements (18, 19, 20, 21) are thyristors or transistors (e.g. MOSFETs or IGBTs) and diodes connected in series with the transistors.