Method and means for controlling a bridge circuit
First Claim
1. A method for controlling a bridge circuit for providing current or power to a load, said bridge circuit comprising one or several legs, each comprising two semiconductor members connected in series between positive and negative power supply rails, each semiconductor member comprising a switchable member for conducting current to or from the load in the forward direction of the semiconductor member under control of a control drive circuit, and a flywheel diode for conducting current in the opposite direction, the method comprising the steps of:
- connecting an LC-circuit between the bridge circuit and the load;
monitoring the bridge voltage (E) of the connection between the semiconductor members and the current (I) through the inductance of the LC-circuit;
supplying a firing pulse to one of said switchable members of said semiconductor members for initiating the conduction thereof;
terminating the conduction of said switchable member when the current (I) through the inductance exceeds a preset value (I'"'"'), whereupon the current of the inductance continues to flow another way through the flywheel diode of the opposite semiconductor member and consequently the bridge voltage (E) changes polarity a first time to the opposite rail polarity until the magnetic energy of the inductance has been terminated resulting in a second change of polarity of the bridge voltage (E) towards the first rail polarity,sensing the change of the polarity of the bridge voltage (E) towards the first rail polarity or otherwise detecting that the bridge or inductance current is zero and supplying another firing pulse at or after said change.
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Accused Products
Abstract
A method and device for controlling a bridge circuit for providing current or power to a load. The bridge comprises two transistors including flywheel diodes and connected in series between positive and negative power supply rails for conducting current to or from the load under control of a control drive circuit. An LC-circuit is connected between the bridge circuit and the load. The bridge voltage (E) of the connection between the two transistors and the current (I) through the inductance of the LC-circuit are monitored and a firing pulse is supplied to one of the transistors. When the current (I) through the inductance exceeds a preset value (I'"'"'), the transistors is turned OFF, whereupon the current of the inductance continues to flow another way through the flywheel diode of the opposite semiconductor member and consequently the bridge voltage (E) changes polarity a first time to the opposite rail polarity until the magnetic energy of the inductance has been terminated resulting in a second change of polarity of the bridge voltage (E) towards the first rail polarity. The change of the polarity of the bridge voltage (E) towards the first rail polarity is detected and another firing pulse is supplied at or shortly after said change.
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Citations
10 Claims
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1. A method for controlling a bridge circuit for providing current or power to a load, said bridge circuit comprising one or several legs, each comprising two semiconductor members connected in series between positive and negative power supply rails, each semiconductor member comprising a switchable member for conducting current to or from the load in the forward direction of the semiconductor member under control of a control drive circuit, and a flywheel diode for conducting current in the opposite direction, the method comprising the steps of:
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connecting an LC-circuit between the bridge circuit and the load; monitoring the bridge voltage (E) of the connection between the semiconductor members and the current (I) through the inductance of the LC-circuit; supplying a firing pulse to one of said switchable members of said semiconductor members for initiating the conduction thereof; terminating the conduction of said switchable member when the current (I) through the inductance exceeds a preset value (I'"'"'), whereupon the current of the inductance continues to flow another way through the flywheel diode of the opposite semiconductor member and consequently the bridge voltage (E) changes polarity a first time to the opposite rail polarity until the magnetic energy of the inductance has been terminated resulting in a second change of polarity of the bridge voltage (E) towards the first rail polarity, sensing the change of the polarity of the bridge voltage (E) towards the first rail polarity or otherwise detecting that the bridge or inductance current is zero and supplying another firing pulse at or after said change. - View Dependent Claims (2, 3, 4, 5)
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6. A means for controlling a bridge circuit for providing current or power to a load, said bridge circuit comprising one or several legs, each comprising two semiconductor members connected in series between positive and negative power supply rails, each semiconductor member comprising a switchable member for conducting current to or from the load in the forward direction of the semiconductor member under control of a control drive circuit, and a flywheel diode for conducting current in the opposite direction by said means comprising
an LC-circuit connected between the bridge circuit and the load; -
a monitor circuit for monitoring the bridge voltage (E) of the connection between the two semiconductor members and the current (I) through the inductance of the LC-circuit, said monitoring circuit comprising a first comparator for comparing when the current (I) through the inductance exceeds a present value (I'"'"') and a second comparator for comparing when the bridge voltage (E) changes polarity towards the corresponding rail polarity; a drive circuit being adapted to provide a firing pulse to one of said switchable members of said semi-conductor members for initiating the conduction thereof; said control drive circuit being adapted to terminate the conduction of said switchable member when said first comparator determines that the current through the inductance exceeds said preset value (I'"'"') and to supply another firing pulse when said second comparator determines that the bridge voltage (E) changes towards the corresponding rail polarity. - View Dependent Claims (7, 8, 9, 10)
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Specification