RU95943U1 - ELECTRONIC START-UP CONTROL UNIT FOR DISCHARGE LAMP - Google Patents

Abstract

 Electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit, containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor and a clamp, shunting the output terminals of the rectifier, the clamp includes the first and second serial circuits respectively, from four counter diodes and two capacitors, shunting the middle diodes of the first series circuit, the common connection points of the middle diodes of the first series circuit and capacitors of the second series circuit of the clamp are connected to the input terminals of the rectifier, a single-phase half-bridge inverter on transistors with counter-parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected filter capacitors, a switching capacitor and a switching inductor, forming a series resonant circuit with a discharge lamp connected to the output terminals of the inverter, formed by a common they are the connection points of the filter capacitors and transistors, respectively.

Description

The utility model relates to instrumentation, lighting, and also to converting technology and can be used in the design of power supplies for fluorescent and other types of energy-saving gas-discharge lamps, as well as various high-frequency, including electrotechnological loads. The utility model extends the scope of application of an electronic ballast for a discharge lamp.

Known electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit, containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor, shunting the output terminals of the rectifier, a single-phase half-bridge inverter on transistors with oncoming parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected to filter capacitor, a switching capacitor and a switching inductor, forming a series resonant circuit connected to the output terminals of the inverter, formed by common points of the connection of the filter capacitors and transistors, respectively (Platan. Electronic components. Catalog. - Publishing House Platan Components, 2008). - S.15).

The disadvantage of an electronic ballast for a gas discharge lamp is its narrow scope due to high levels of harmonic components of the current consumed from the network, large amplitudes of the currents of the network and increased pulsations of the light flux of the gas discharge lamp, as well as insufficient reliability of the device.

Known electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit, containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor, shunting the output terminals of the rectifier, a single-phase half-bridge inverter on transistors with oncoming parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, including in addition two connected in series filter capacitors, a three-winding transformer, as well as a switching capacitor and a switching inductor, forming a series resonant circuit connected to the inverter output terminals formed by the common connection points of the filter capacitors and transistors with a gas discharge lamp, respectively, the base of the transistor is connected to the emitter through a series a circuit from the secondary winding of a transformer connected counter to the primary winding, and a resistor, transistor shun doped with a damper capacitor and second and third resistors connected in series, the emitter of the transistor is connected to the collector of the second transistor through the fourth resistor, the base of the second transistor is connected to the emitter through the second serial circuit from the second secondary winding of the transformer connected in accordance with the primary winding, and the fifth resistor, the emitter of the second the transistor is connected to the output terminal of the rectifier through a sixth resistor (IR2520 - new opportunities in the development of electronic ballasts // Silov I electronics. - 2006. - No. 2. - S.26).

The disadvantage of an electronic ballast for a gas discharge lamp is its narrow scope due to the low value of the efficiency, high harmonic components of the current consumed from the network, large amplitudes of the currents of the network, increased ripple of the light flux and values of the shape factor of the current of the discharge lamp, as well as insufficient reliability device operation.

Known electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit, containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor, shunting the output terminals of the rectifier, a single-phase half-bridge inverter on transistors with oncoming parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected to a filter capacitor, a three-winding transformer, as well as a switching capacitor and a switching inductor, forming a series resonant circuit connected to the inverter output terminals formed by the common connection points of the filter capacitors and transistors with a gas discharge lamp, respectively, the base of the transistor is connected to the emitter via a serial circuit from the secondary winding of the transformer included in the opposite direction with the primary winding, and the resistor, the base of the second transistor The ora is connected to the emitter through a second serial circuit from the second secondary winding of the transformer, connected in accordance with the primary winding, and the second resistor (Otero Pascal.M. Motorola's D2 Series Transistors for Fluorescent Converters. - Motorola, 1997 .-- AN1577).

The specified electronic ballast for a discharge lamp is the closest in technical essence to a utility model and is selected as a prototype.

The disadvantage of the prototype is the narrow scope due to the low value of the efficiency, high harmonic components of the current consumed from the network, large amplitudes of the current network, increased ripple of the light flux and the values of the shape factor of the current of the discharge lamp, as well as insufficient reliability of the device.

The utility model is aimed at solving the problem of expanding the scope of application of an electronic ballast for a gas discharge lamp, which is the purpose of the utility model.

This goal is achieved by the fact that in an electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor and a clamp, shunting the output terminals of the rectifier, the clamp includes the first and second series circuits, respectively, of four counter diodes and two capacitors, shunting the middle diodes of the first follower circuit, common points of connection of the middle diodes of the first series circuit and the capacitors of the second series circuit of the clamp are connected to the input terminals of the rectifier, a single-phase half-bridge inverter on transistors with counter-parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected filter capacitors switching capacitor and switching inductor forming a series resonant circuit connected to the output with a discharge lamp one of the conclusions of the inverter, formed by common points of connection of the filter capacitors and transistors, respectively.

A significant difference characterizing the utility model is the expansion of the scope, which is achieved by a comprehensive increase in the value of the efficiency, lowering the levels of harmonic components of the current consumed from the network, reducing the amplitudes of the currents of the network, ripple of the light flux and values of the shape factor of the current of the discharge lamp, as well as increasing the reliability the operation of the device through the use of an effective rectification and filtration scheme (stamp), optimization of the starting mode of the device, reducing Nia switching losses in the transistors and diodes of the inverter rectifier, and electrical losses in the other components of the apparatus. The inventive electronic ballast can be used for energy-saving applications that ensure stabilization of the light flux during the life of a discharge lamp, including for new types of compact fluorescent lamps.

The expansion of the scope of the electronic ballast for a gas discharge lamp is the technical result due to new elements in the circuit, the order of their inclusion and new connections, that is, the hallmarks of the utility model. Thus, the distinguishing features of the claimed electronic ballast for a discharge lamp are significant.

Figure 1 shows a diagram of an electronic ballast for a gas discharge lamp, figure 2 comparative waveforms of currents and voltages in the circuit of the prototype and the inventive ballast for a gas discharge lamp.

The electronic ballast for a gas discharge lamp 1 connected to the output terminals of the device in a serial resonant circuit contains a single-phase bridge rectifier on four diodes 2-5, the input terminals of which are connected to the input terminals of the device, a filter capacitor 6 and a clamp, shunting the output terminals of the rectifier, a clamp includes the first and second series circuits, respectively, of four counter diodes 7-10 and two capacitors 11, 12, shunting the middle diodes of the first series circuit, common points the connections of the middle diodes of the first series circuit and the capacitors of the second series circuit of the clamp are connected to the input terminals of the rectifier, a single-phase, half-bridge inverter on transistors 13, 14 with counter-parallel diodes 15, 16, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected filter capacitor 17, 18, a switching capacitor 19 and a switching inductor 20, forming a series resonant circuit connected to the output with a discharge lamp A output of the inverter formed by the common connection points of the filter capacitors and transistors, respectively.

Electronic ballast for a discharge lamp in steady state operates as follows. A single-phase bridge rectifier on diodes 2-5 converts the alternating voltage of the network into alternating voltage. With an increase in the equivalent load resistance (close to the full utilization of the lamp resource 1), the voltage at the rectifier output increases due to the operation of the capacitors 11, 12 of the second sequential clamp circuit, which stabilizes the combustion mode and the light flux of the discharge lamp 1. Thus, in the new electronic ballast for a gas discharge lamp there is an effective parametric stabilization in case of violations of the electric mode. The filter capacitor 6 together with the clamp capacitors 11, 12 provides a sufficiently high-quality and reliable filtering of the output voltage of the rectifier. The filter capacitor 6 is charged from the power source (rectifier) and through the clamp capacitors 11, 12. As a result, the output voltage at the input terminals of the inverter is more stable, and the current pulses of the network have a smaller amplitude and a longer duration. The diodes 7-10 of the first series circuit of the clamp cut off the capacitors 11, 12 of the first series circuit from the filter capacitor 6 at a high level of instantaneous voltage at the rectifier output, which ensures the operation of the electronic ballast for a discharge lamp 1 with a sufficiently high power factor. Transistors 13, 14 of a single-phase half-bridge inverter are turned on and conduct current alternately. The inverter operates (in a particular case) in the self-generating mode, which is achieved by applying a sequential resonant circuit to turn on the discharge lamp 1 through a switching capacitor 19 and a switching inductor 20 between the input terminals of the inverter formed by the common connection points of the filter capacitors 17, 18 and transistors 13, 14, respectively. Periodic switching of transistors 13, 14 occurs with a frequency determined by the capacitance of the switching capacitor 19 and the inductance of the switching inductor 20. The current in the load circuit has a quasi-sinusoidal shape. Counter-parallel diodes 15, 16 limit the magnitude of the reverse voltages on the transistors 13, 14 of the inverter. From a comparison of the waveforms of figure 2 currents and voltages in known circuits, including in the prototype circuit (first and second waveforms) and a new electronic ballast for gas discharge lamp 1 (third and fourth waveforms) it follows that the ripple of the input voltage of the inverter is reduced ( the total capacitance of the capacitors 6, 11, 12 in the new apparatus is two times less), therefore, the pulsation of the light flux is significantly reduced. The output voltage of the rectifier in the new ballast for gas discharge lamp 1 has a higher level due to the action of the clamp (elements 7-12), which allows the use of series connection circuits of gas discharge lamps 1 in multi-lamp fixtures. The amplitude of the current pulses of the network in the new apparatus with equal output power is much lower. The network current, as can be seen from a comparison of the first and third waveforms, has a better shape factor and a much lower amplitude (about 1.1 A instead of 2.0 A) with comparable power factors.

The output voltage of the inverter, as already noted, can have a higher level (average value) with equal values of the installed capacitance, which provides significant advantages of the new electronic ballast for a discharge lamp 1.

Inverter transistors 13, 14 can be performed with structures with built-in anti-parallel diodes or modular designs with pre-installed anti-parallel diodes. In this case, there is no need to install separate (discrete) counter-parallel diodes 15, 16. The filter capacitor 6 is electrolytic or film with a capacitance of about 0.13 μF / W. Capacitors 11, 12 can also be electrolytic or film with a capacitance of about 0.05 μF / W. Counter-parallel diodes 15, 16 should be fast. Diodes 2-5 are conventional low frequency rectifier diodes.

Compared with the prototype, the scope of application of an electronic ballast for a discharge lamp is significantly expanded. The inventive electronic ballast can be used for energy-saving applications, providing, for example, stabilization of the light flux during the life of a discharge lamp, including for compact fluorescent lamps. This is achieved through a comprehensive increase in the efficiency of the device, lowering the levels of harmonic components of the current consumed from the network, reducing the amplitudes of the currents of the network, ripple of the light flux and the values of the shape factor of the current of the discharge lamp, as well as increasing the reliability of the device. Positive qualities are due to the use of an effective single-phase bridge rectifier with high-quality filtering of the output voltage and a stamp, a decrease in switching losses in the inverter transistors and rectifier diodes, as well as electrical losses in other elements of the device. Increases the stability and, therefore, the reliability of the electronic ballast for a gas discharge lamp. Disruption of inversion during dynamic load operation is excluded. The level of output voltage increases, which allows to reduce the magnitude of the currents through the active elements of the device and expands the possibilities for improving the design of multi-lamp fixtures. An increase in the output voltage level with an increase in the equivalent load resistance makes it possible to stabilize the luminous flux of a discharge lamp during the entire service life and increase the period of effective use.

Improving the reliability of an electronic ballast for a discharge lamp is estimated by the mean time between failures. In accordance with the results of experimental studies, the time between failures of the claimed apparatus can be increased by 40-50%.

The efficiency of the device is increased by 3-4% due to the reduction of energy losses in the elements, including due to a significant decrease in the amplitudes of the pulses of the input current of the device and its shape factor.

The design can be greatly simplified and the price of the device can be reduced by optimizing the circuit and making it possible to use transistors and diodes with reduced requirements for their parameters and a lower price.

Compared with the prototype, the weight and dimensions of the inventive electronic ballast for a gas discharge lamp can be reduced due to the optimization of the circuit and design, which also expands the scope of its application.

Claims (1)

Electronic ballast for a gas discharge lamp connected to the output terminals of the device in a serial resonant circuit, containing a single-phase bridge rectifier on diodes, the input terminals of which are connected to the input terminals of the device, a filter capacitor and a clamp, shunting the output terminals of the rectifier, the clamp includes the first and second serial circuits respectively, from four counter diodes and two capacitors, shunting the middle diodes of the first series circuit, the common connection points of the middle diodes of the first series circuit and capacitors of the second series circuit of the clamp are connected to the input terminals of the rectifier, a single-phase half-bridge inverter on transistors with counter-parallel diodes, the input terminals of which are connected to the output terminals of the rectifier, which also includes two series-connected filter capacitors, a switching capacitor and a switching inductor, forming a series resonant circuit with a discharge lamp connected to the output terminals of the inverter, formed by a common they are the connection points of the filter capacitors and transistors, respectively.