RU77730U1 - VOLTAGE CONVERTER PROTECTED FROM OVERLOAD - Google Patents

Abstract

A voltage converter with overload protection refers to high-frequency transistor converters used in secondary power supply circuits (IVEP), and more specifically to devices for protecting against failures of switched elements and magnetizing transformers of inverter circuits. The utility model can be used in protection devices of switched elements, such as IGBT, and other semiconductor elements used in inverter circuits. The objective of the utility model is to provide protection for the converter, which operates at a relatively constant high output frequency, and which ensures the normal switching of controlled key elements. To solve the problem in a voltage converter with overload protection, containing a high-frequency converter, the first input of which is connected to the first output of the power source through a current sensor, its second input is connected to the second output of the power source, the first and second outputs are connected respectively to the first and second the terminals of the primary winding of the transformer, the first and second conclusions of the secondary winding of which are connected in series through the rectifier and the LC filter respectively to the first to the second output terminals of the voltage converter, the current sensor is connected to the first input of the converter through a current limiting inductor, one end connected to the anode of the diode, the cathode of which is connected to the current sensor, the output of the current sensor is connected to one of the inputs of the feedback amplifier, to the other input of which the reference voltage is supplied from an external controller, and its output is connected to

Description

The utility model relates to high-frequency transistor converters used in circuits of secondary power sources (IVEP), and more specifically to devices for protecting against failures of switched elements and magnetizing transformers of inverter circuits. The invention relates to protection devices for switched elements, such as IGBT, and other semiconductor elements used in inverter circuits. For many applications, in particular for power supply systems used on spacecraft, there is a need for the inverter stage to be lightweight and costly, sufficiently simple and reliable. Another requirement is that the power supply systems operate on alternating current with a frequency much higher than conventional ground-based power supply systems, for example, 50 kHz, to further reduce the weight of other elements of the power supply system. Converters for such systems converting direct current to high frequency alternating current are quite complex, and often do not have sufficient protection against emergency conditions.

In known converters (Japanese patent. No. 449348, "Method and device for protecting the PWM inverter against current overload", US patent No. 5175676, "Advanced short circuit protection for DC-AC converters") to protect power switches from current overload and short circuits, a current sensor and threshold devices are used, which either turn off the converter or put it into current limiting mode. However, in transistor power switches in bridge circuits, due to the high slew rate, current sensors and threshold devices do not provide protection against failure of transistors on one arm, if for some reason they turn out to be open. The installation of limiting resistors and chokes in the shoulders of the bridge reduces the efficiency and increases the size. When the converter is turned on and off, transients occurring in the reactive elements can disable power switches.

Known schemes of voltage converters with overload protection, containing a current sensor in the input power circuit and a protection unit included in the power circuit of the converter control unit (see RF patents No. 1065996, RF patent No. 2110133). The disadvantage of such circuits is that when the current changes abruptly, the protection does not have time to trip, and a large current passes through the power keys, which can lead to a malfunction of the inverter, or even to failure of key elements.

The closest in technical essence to the proposed utility model is a voltage converter with overload protection according to RF patent No. 2269195, containing a high-frequency converter, the first input of which is connected through the current sensor to the first output of the power source, its second input is connected to the second output of the power source, the first and its second outputs are connected respectively to the first and second terminals of the primary winding of the transformer, the first and second conclusions of the secondary winding of which are connected in series through nennye rectifier and LC-filter are connected respectively to first and second output terminals of the converter. The first input of the feedback unit, the second input of which is connected to the output of the rectifier, is connected to the first output terminal of the converter, the output of the feedback unit is connected to the first input of the control unit. The control unit contains a master oscillator and a driver of the control signal, made on the basis of a pulse-width modulator. The feedback element is based on an optocoupler. To prevent blocking of the high-frequency converter at Inag> Imax, a transistor switch is introduced through which the switching surge occurs. Further protection based on feedback is triggered.

Despite a slight increase in stability when transients occur, the circuit does not protect the key elements of the inverter from a sudden change in current, as a result of which power transistors can fail due to an abnormal increase in current.

The objective of the utility model is to provide protection for the converter, which operates at a relatively constant high output frequency, and which ensures the normal switching of controlled key elements.

The problem is solved in that in a voltage converter with overload protection containing a high-frequency converter, the first input of which is connected to the first output of the power source through a current sensor, its second input is connected to the second output of the power source, the first and second outputs are connected respectively to the first and the second terminals of the primary winding of the transformer, the first and second terminals of the secondary winding of which are connected in series through the rectifier and the LC filter respectively to the transformer to the second and second outputs of the voltage converter, the current sensor is connected to the first input of the converter through a current limiting inductor, one end connected to the anode of the diode, the cathode of which is connected to the current sensor, the output of the current sensor is connected to one of the inputs of the feedback amplifier, to the other input of which reference voltage from an external controller, and its output is connected to a high-speed comparator

cut-off connected to a control unit containing a driver of the control signal, made on the basis of a pulse-width modulator, the outputs of which are connected to the control inputs of a high-frequency voltage converter.

Further, the essence of the utility model is illustrated in the figure, which shows a diagram of a voltage converter with protection against current overload.

The voltage converter with overload protection contains a high-frequency converter (inverter) 1, the first input of which is connected to the first output of the power source through a series-connected current sensor 2 and a current limiting inductor 3, and its second input is connected directly to the second output of the power source. The circuit including the current sensor 2 and the inductor 3 is shunted by the diode 4, the anode of which is connected to the inductor 3, and the cathode is connected to the current sensor 2. The output terminals of the high-frequency converter are connected to the primary winding 5 _{1 of the} transformer 5 secondary winding

which 5 ₂ through a series-connected rectifier 6 and an LC filter 7 is connected to the output terminals of the Converter. The output of the current sensor 2 is connected to the first input of the feedback amplifier 8, based on the operational amplifier. The output of the feedback amplifier 8 is connected to a high-speed cutoff comparator 9 connected to a control unit 10, which includes a control signal generator based on a pulse-width modulator, the outputs of which are connected to the control inputs of the high-frequency converter 1. The reference voltage is applied to the other input of the comparator 9 (U _op ), which is the voltage for overcurrent protection

The device operates as follows:

When a voltage is supplied from the power source, the control unit 10 starts to generate pulses that are fed to the control inputs of the high-frequency voltage converter 1. Current flows through the primary winding 5 _{1 of the} transformer, which is induced into the secondary winding 5 ₂ and through the rectifier 6 and the LC filter 7 fed to the load connected to the output of the Converter. At the same time, from the output of the current sensor 2, the current converted to voltage, through the operational amplifier 8, is fed to the input of a high-speed comparator 9, to the other input of which a reference voltage (U _op ) is supplied.

Upon receipt of the error signal, the signal from the comparator 9 is fed to the input of the control unit 10, where it is converted into a pulse signal by which the converter 1 is controlled. If there is no overvoltage at the output of the comparator 8, there is no signal. In case of sharp switching processes, when the input current exceeds the maximum permissible current with a high slew rate,

due to the presence of a delay, the error signal from the comparator 9 may arrive late to the control unit 10, and may not provide protection against the failure of transistors of the high-frequency converter. At the same time, in the proposed device, the input current before it arrives at the inverter transistors is supplied to the inductor 3, where the slew rate of the current slows down to about 1a / μs. During this time, the mismatch signal from the comparator 9 arriving at the control unit 10 manages to provide a ban signal for switching transistor switches of the high-frequency converter 1. Through diode 2, the voltage on the inductor 3 drops, as soon as its value is equal to the nominal value, the mismatch signal disappears from the control unit a signal is received that permits the normal operation of the transistors of inverter 1. Until the emergency current in the current limiting choke decreases, the control of the inverter power keys is blocked.

The proposed inverter protection circuit allows you to protect key transistor elements from incorrect switching and failure.

Claims (1)

An overload protection voltage converter comprising a high-frequency converter (inverter), the first input of which is connected to the first output of the power source through a current sensor, its second input is connected to the second output of the power source, its first and second outputs are connected respectively to the first and second terminals of the primary transformer windings, the first and second conclusions of the secondary winding of which are connected through a rectifier and an LC filter in series to the first and second output terminals, respectively A voltage converter, characterized in that the current sensor is connected to the first input of the converter through a current limiting inductor, one output of which is connected to the anode of the diode, the cathode of which is connected to the specified current sensor, the output of the current sensor is connected to one of the inputs of the feedback amplifier associated with high-speed a cutoff comparator, to the other input of which the reference voltage is supplied from an external controller, and its output is connected to a control unit containing a control signal shaper made on Nove pulse width modulator, the outputs of which are connected to the control inputs of the high frequency voltage converter (inverter).