DE102021206671A1 - DC/DC converters and frequency converters - Google Patents

Abstract

1. DC/DC converter (100), having: - a transformer (1) with a primary winding (1a) and a secondary winding (1b), - a switching transistor (2), - a safety transistor (3), - a current sensor ( 4), - a first control unit (5), - a second control unit (6), - wherein the primary winding (1a), the switching transistor (2) and the safety transistor (3) in series between a first converter branch (7) on which a positive converter potential (ZK+) is present, and a second converter branch (8), at which a negative converter potential (ZK-) is present, are looped in, - the current sensor (4) being designed to detect a current flowing through the safety transistor (3). to measure, - wherein the first control unit (5) is designed to drive the switching transistor (2), and - wherein the second control unit (6) is coupled to the current sensor (4) and is designed to control the safety transistor (3) in such a way to control that this opens when a means of the current sensor (4) g The measured current exceeds a threshold value, and- at least one rectifier element (9) for generating a DC supply voltage (USG) by rectifying a voltage present at the secondary winding (1b).

Description

The object of the invention is to provide a DC/DC converter and a frequency converter with such a DC/DC converter which have a high level of operational reliability.

The DC/DC converter has an in particular galvanically isolating transmitter or transformer with a primary winding and a secondary winding.

The DC/DC converter further includes: a switching transistor, a safety transistor, a current sensor, a first control unit and a second control unit. The first control unit can be separate from the second control unit. Alternatively, the first control unit and the second control unit can also be integrated as different functional blocks in a superordinate control unit, which is implemented, for example, as a microprocessor control or the like.

The primary winding, the switching transistor and the safety transistor are looped in series between a first converter branch, at which a positive converter potential is present during operation of the DC/DC converter, and a second converter branch, at which a negative converter potential is present during operation of the DC/DC converter pending.

The current sensor is designed to measure a current flowing through the safety transistor.

The first control unit is conventionally designed to drive the switching transistor to operate the DC/DC converter in a pulsed manner.

The second control unit is coupled to the current sensor and designed to control the safety transistor in such a way that it opens when a current measured by the current sensor exceeds a threshold value. The threshold value is dimensioned in such a way that it is only exceeded if the switching transistor is defective, i.e. should theoretically be blocked or open, but due to a fault/defect in the switching transistor and/or the circuit periphery of the switching transistor, a current flow via and/or along the switching transistor is possible.

On the secondary side, the DC/DC converter has at least one rectifier element for generating a DC feed voltage by rectifying a voltage present at the secondary winding. The DC supply voltage can be galvanically isolated from the positive converter potential and the negative converter potential.

In one embodiment, the current sensor has a shunt resistor or is a shunt resistor, the primary winding, the switching transistor or its drain-source path or collector-emitter path, the safety transistor or its drain-source path or collector-emitter path and the shunt resistor are looped in series between the first converter branch and the second converter branch.

In one embodiment, the DC/DC converter has a voltage sensor that measures a voltage after the switching transistor, in particular against the negative converter potential. The voltage sensor can, for example, measure a voltage between a connecting node of the switching transistor and the safety transistor in relation to the negative converter potential. The second control unit is coupled to the voltage sensor and designed to control the safety transistor in such a way that it opens or remains open when a voltage measured by the voltage sensor exceeds a threshold value when the switching transistor is controlled in such a way that it should be open. The threshold value is dimensioned in such a way that it is only exceeded if the switching transistor is defective, i.e. should theoretically be blocked or open, but due to a fault/defect in the switching transistor and/or the circuit periphery of the switching transistor, a current flow via and/or along the switching transistor is possible.

In one embodiment, the DC/DC converter has a level converter, in particular a step-up converter, the first control unit driving the switching transistor with the level converter connected in between.

In one embodiment, the at least one rectifier element is a diode or has a diode.

In one embodiment, the DC/DC converter is a flyback converter.

In one embodiment, the first control unit is coupled to the current sensor and is designed to control the switching transistor as a function of the current measured by the current sensor.

In one embodiment, the DC supply voltage has a voltage level in a range between 3.3V and 48V.

The frequency converter has a conventional DC voltage intermediate circuit with a first intermediate circuit branch, at which a positive intermediate circuit potential is present, and a second intermediate circuit branch, at which a negative intermediate circuit potential is present. The potential difference between the positive and negative intermediate circuit potential is referred to as the intermediate circuit voltage and can be 800 V, for example. The frequency converter also has a DC/DC converter as described above, the first intermediate circuit branch being electrically connected to the first converter branch and the second intermediate circuit branch being electrically connected to the second converter branch, ie the positive converter potential and the positive intermediate circuit potential identical and that. the negative converter potential and the negative intermediate circuit potential are identical. In other words, the DC/DC converter is fed from the intermediate circuit voltage.

In one embodiment, the frequency converter has at least one component that is fed from the DC supply voltage.

According to the invention, two transistors, namely the switching transistor and the safety transistor, are connected in series. If one of the two transistors is short-circuited, the other switching transistor can switch off safely.

The switching transistor is conventionally driven by the first control unit with switching pulses. A level converter can be connected between the first control unit and the switching transistor, which ensures the isolation voltage in the event of a fault when the safety transistor is blocked.

The safety transistor is continuously activated in normal operation and is therefore always conductive. If, for example, the switching transistor is short-circuited for the purpose of a UL test, the current through the current sensor increases despite the switching transistor being open, and the second control unit switches the safety transistor off permanently when the current threshold value is exceeded. The circuit is not reset until the mains is switched off and then switched on again, provided that the voltage measured by the voltage sensor does not exceed a specific threshold value. A short-circuited or defective switching transistor means that this is detected when switching on, since a voltage is measured by the voltage sensor. In this case the DC/DC converter does not start. If the safety transistor is short-circuited, this does not affect the normal operation of the DC/DC converter, since the safety transistor is always closed in normal operation.

A fire can be prevented by means of the invention if the switching transistor is faulty closed, since in this case the current flow caused by the fault can be interrupted by means of the safety transistor.

• 1 einen Frequenzumrichter mit einem erfindungsgemäßen DC/DC-Wandler.

The invention is described in detail below with reference to the drawing. This shows:

• 1 a frequency converter with a DC/DC converter according to the invention.

1 shows a frequency converter 200 with a conventional DC voltage intermediate circuit 201. The DC voltage intermediate circuit 201 has a first intermediate circuit branch 202, at which a positive intermediate circuit potential ZK+ is present during operation, and a second intermediate circuit branch 203, at which a negative intermediate circuit potential ZK− is present during operation. pending. An intermediate circuit capacitor 205 is connected between the first intermediate circuit branch 202 and the second intermediate circuit branch 203 .

The frequency converter also has a DC/DC converter in the form of a flyback converter 100 .

The DC/DC converter 100 has a transformer 1 with a primary winding 1a and a secondary winding 1b.

On its primary side, the DC/DC converter 100 has: a switching transistor 2, a safety transistor 3, a current sensor 4 in the form of a shunt resistor, a first control unit 5, and a second control unit 6, with the primary winding 1a, the switching transistor 2 the safety transistor 3 and the shunt resistor 4 are looped in series between a first converter branch 7, at which a positive potential ZK+ is present, and a second converter branch 8, at which a negative potential ZK- is present. The current sensor 4 is designed to measure a current flowing through the safety transistor 3 . The first control unit 5 is designed to drive the switching transistor 2 . The second control unit 6 is coupled to the current sensor 4 and is designed to control the safety transistor 3 in such a way that it opens when a current measured by the current sensor 4 exceeds a threshold value.

On its secondary side, the DC/DC converter 100 has at least one rectifier element 9 in the form of a diode for generating a supply DC voltage USG, which is generated by rectifying a voltage present at the secondary winding 1b. The DC supply voltage USG has a voltage level in a range between 3.3 V and 48 V and is smoothed using a smoothing capacitor 12 .

The first intermediate circuit branch 202 is electrically connected to the first converter branch 7 and the second intermediate circuit branch 203 is electrically connected to the second converter branch 8 .

The frequency converter 200 has at least one component or an electrical load 204 which is fed from the DC supply voltage USG.

The DC/DC converter 100 has a voltage sensor 10 which measures a voltage between the switching transistor 2 and the safety transistor 3 . The second control unit 6 is coupled to the voltage sensor 10 and is designed to control the safety transistor 3 in such a way that it opens or remains open when a voltage measured by the voltage sensor 10 exceeds a threshold value when the switching transistor 2 is controlled in such a way that it should be open. In this way, a current flow is prevented when the switching transistor 2 is defective.

The DC/DC converter 100 has a level converter 11, the first control unit 5 driving the switching transistor 2 with the level converter 11 being connected in between.

The first control unit 5 is coupled to the current sensor 4 and is designed to control the switching transistor 2 as a function of the current measured by the current sensor 4 .

Claims (10)

DC/DC converter (100) comprising: - a transformer (1) with a primary winding (1a) and a secondary winding (1b), - a switching transistor (2), - a safety transistor (3), - a current sensor (4), - a first control unit (5), - a second control unit (6), - Wherein the primary winding (1a), the switching transistor (2) and the safety transistor (3) in series between a first converter branch (7) to which a positive converter potential (ZK+) is present, and a second converter branch (8) to which a negative converter potential (ZK-) is present, are looped in, - wherein the current sensor (4) is designed to measure a current flowing through the safety transistor (3), - wherein the first control unit (5) is designed to drive the switching transistor (2), and - wherein the second control unit (6) is coupled to the current sensor (4) and is designed to control the safety transistor (3) in such a way that it opens when a current measured by the current sensor (4) exceeds a threshold value, and - At least one rectifier element (9) for generating a DC supply voltage (USG) by rectifying a voltage present on the secondary winding (1b). DC/DC converter (100) according to claim 1 , characterized in that - the current sensor has a shunt resistor (4), the primary winding (1a), the switching transistor (2), the safety transistor (3) and the shunt resistor (4) in series between the first converter branch ( 7) and the second converter branch (8) are looped in. DC/DC converter (100) according to one of the preceding claims, characterized in that - the DC/DC converter (100) has a voltage sensor (10) which measures a voltage after the switching transistor (2), the second control unit (6) is coupled to the voltage sensor (10) and is designed to control the safety transistor (3) in such a way that it opens or remains open when a voltage measured by the voltage sensor (10) exceeds a threshold value when the switching transistor (2 ) is controlled in such a way that it should be open. DC/DC converter (100) according to one of the preceding claims, characterized in that - the DC/DC converter (100) has a level converter (11), the first control unit (5) switching the switching transistor (2) with the interposition of the Level converter (11) drives. DC/DC converter (100) according to one of the preceding claims, characterized in that - the at least one rectifier element is a diode (9). DC/DC converter (100) according to one of the preceding claims, characterized in that - the DC/DC converter (100) is a flyback converter. DC/DC converter (100) according to one of the preceding claims, characterized in that - the first control unit (5) is coupled to the current sensor (4) and is designed to switch the switching transistor (2) as a function of the means of the current sensor (4) drive measured current. DC/DC converter (100) according to one of the preceding claims, characterized in that that - the DC supply voltage (USG) has a voltage level in a range between 3.3 V and 48 V. Frequency converter (200), comprising: - a DC voltage intermediate circuit (201), with a first intermediate circuit branch (202) at which a positive intermediate circuit potential (ZK+) is present, and a second intermediate circuit branch (203) at which a negative intermediate circuit potential (ZK-) is present, and - A DC / DC converter (100) according to any one of the preceding claims, wherein the first intermediate circuit branch (202) is electrically connected to the first converter branch (7), and the second intermediate circuit branch (203) to the second converter branch ( 8) is electrically connected. Frequency converter (200) after claim 9 , characterized in that - the frequency converter (200) has at least one component (204) which is fed from the DC supply voltage (USG).

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