Single-switch electronic dimming ballast

Electric lamp and discharge devices: systems – Periodic switch in the supply circuit – Silicon controlled rectifier ignition

Reexamination Certificate

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Details

C315S244000, C315S224000, C315S307000, C315SDIG004

Reexamination Certificate

active

06791279

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to electronic ballasts for gas discharge lamps, and more particularly, to a single-switch-inverter-based electronic dimming ballast for a fluorescent lamp.
BACKGROUND OF THE INVENTION
Electronic ballasts for fluorescent and other gas discharge lamps are well known. A typical topology for an electronic ballast uses a half-bridge inverter circuit containing two semiconductor switching devices such as two metal oxide semiconductor field effect transistors (MOSFETs). The inverter receives DC voltage provided by rectifying, and at least partly filtering, voltage from an AC supply, and delivers high frequency AC current, typically at a frequency of a few tens of kilohertz, to a fluorescent lamp.
There have recently been proposed ballasts using only a single semiconductor switching device in the inverter. By eliminating a second semiconductor switching device, these ballasts advantageously have reduced cost and reduced power dissipation. An example of such a ballast is described in commonly-assigned U.S. patent application Ser. No. 10/006,036, filed Dec. 5, 2001, entitled “Single Switch Electronic Dimming Ballast”, which is herein incorporated by reference in its entirety.
One ballast described in that earlier application includes a transformer having a primary winding, a secondary winding, and a magnetizing inductance associated therewith. A semiconductor switching device is connected to the primary winding for applying a voltage across the primary winding. The secondary winding of the transformer supplies a current to a lamp through a resonant circuit, such as an LC resonant tank. When the switching device is conducting, a current is induced in the magnetizing inductance, and when the switching device is not conducting, a portion of the current in the magnetizing inductance flows to the resonant tank. A portion of the current flowing in the resonant tank flows to the fluorescent lamp.
A control circuit determines the operating frequency and duty cycle of the semiconductor switching device. The operating frequency is typically selected to be as close as possible to the resonant frequency of the tank circuit so as to achieve needed performance in terms of voltage gain, waveform smoothing, and ballast output impedance. However, if the operating frequency is set too close to the resonant frequency of the tank, then there are significant power losses due to circulating currents.
The maximum value of the magnetizing inductance of the transformer is limited by the maximum power that needs to be supplied to the lamp. The magnetizing inductance has hitherto been set as high as possible, however, so as to minimize currents through the switching device and the transformer. Excess current causes additional power dissipation that is wasteful and potentially harmful, because it is dissipated as heat in components that may be damaged, or have reduced service lives, if they are overheated. There is thus a clear and well-known motivation to keep excess current to a minimum.
SUMMARY OF THE INVENTION
The present invention is based in one aspect on the discovery that, with certain ballast topologies, when the inverter switch is non-conductive, the magnetizing inductance of the transformer interacts electrically with the resonant tank circuit. As a result, the effective resonant circuit then consists essentially of the original tank circuit, typically a tank capacitor and a tank inductor, plus the magnetizing inductance. The resulting combined circuit has a different, typically lower, resonant frequency than the original resonant tank circuit.
Based on this discovery, the performance of the ballast at low power outputs, when the switch is nonconductive (the “off time”) for a large proportion of the switching period, can be substantially improved by selecting the operating frequency of the ballast in relation to the resonant frequency of the effective resonant circuit including the magnetizing inductance. However, merely lowering the operating frequency can result in diminished ballast performance, especially at high power outputs. In order to avoid diminished performance at high power outputs, when the switch is conductive (the “on time”) for a higher proportion of the switching period, the value of the magnetizing inductance is preferably reduced. The resonant frequency of the combined resonant circuit, including the magnetizing inductance, is thereby brought closer to the resonant frequency of the tank circuit, excluding the magnetizing inductance.
In one aspect, the invention provides an electronic ballast for discharge lamps, comprising a single-switch inverter including an inductor, preferably a magnetizing inductance, and a first resonant circuit, preferably an LC tank circuit, connected to the inverter output, wherein when the inverter switch is non-conductive the inverter inductor forms with the components of the first resonant circuit a second resonant circuit, wherein the operating frequency of the inverter is controlled to be at or below the resonant frequency of the first resonant circuit, and wherein the value of the magnetizing inductance is substantially lower than the maximum value that would permit the ballast to supply its maximum desired output power.
In another aspect, the invention provides an electronic ballast for a fluorescent lamp, comprising a single-switch inverter including an inductor, and a first resonant circuit having a first resonant frequency, wherein when the inverter switch is non-conductive, the inverter inductor combines with an inductance of the first resonant circuit, forming a second resonant circuit having a second resonant frequency lower than the first, wherein the operating frequency of the inverter is below the first resonant frequency, and wherein the operating frequency of the inverter is close to the second resonant frequency.
The operating frequency of the inverter is preferably closer to the second resonant frequency than to the first resonant frequency. Advantageously, the operating frequency of the inverter is no more than half as far from the second resonant frequency as it is from the first resonant frequency. Preferably, the operating frequency of the inverter is less than the second resonant frequency. Stated differently, the invention is an electronic ballast for fluorescent lamps comprising a single-switch inverter including an inductance and having an operating switching period; and a resonant circuit supplied by the inverter and having a first resonant period; wherein when the inverter switch is non-conductive, the inverter inductance interacts with the resonant circuit to define a second resonant period longer than the first resonant period; wherein the operating switching period of the inverter is longer than the first resonant period; and wherein the duration of the operating switching period of the inverter is close to the duration of the second resonant period. Preferably, the duration of the operating switching period of the inverter is closer to the duration of the second resonant period than to the duration of the first resonant period. Most preferably, the duration of the operating switching period of the inverter is no more than half as far from the duration of the second resonant period as it is from the duration of the first resonant period.
The operating frequency may be set between the two resonant frequencies so that the power consumption of the ballast when the ballast is operating under a “no-load” condition is no greater than the power losses in the ballast when operating at full power.
It is possible to vary the operating frequency of the inverter, so as to be closer to the resonant frequency of the first resonant circuit when the duty cycle is high, and to be closer to the second resonant frequency when the duty cycle is low. This control method is not necessary for operation of the ballast, but may be advantageous for some applications, such as, for example, when driving small-diameter lamps. One advantage of the present invention is that it exploits the simplicity, an

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