This application claims priority to German Patent Application Serial No. 10 2009 019 904.7, which was filed May 4, 2009, and is incorporated herein by reference in its entirety.
Various embodiments relate to a circuit arrangement for operating discharge lamps with an input, to which a system voltage from a power supply system can be connected, and an output, to which at least one discharge lamp can be connected, the circuit arrangement having a step-up converter.
Various embodiments are based on a circuit arrangement for operating discharge lamps. Many circuit arrangements for operating discharge lamps have a power factor correction circuit for converting the input voltage into a suitable DC voltage, which is often also regulated, said DC voltage being referred to as the intermediate circuit voltage and then being fed to the inverter. The power factor correction circuit, which is generally a step-up converter in terms of circuit topology, brings about a sinusoidal current consumption of the entire arrangement and at the same time a regulated intermediate circuit voltage of a suitable level. These circuit arrangements are incorporated in control gear for low-pressure or high-pressure discharge lamps and are generally fed by an AC system voltage. In the case of the power factor correction circuit as a step-up converter, the converter switch is arranged between the incoming and return current path of the circuit, i.e. is not directly in the main current path.
In order to keep the intermediate circuit voltage stable and in order to limit ripple currents, such circuit arrangements generally have a so-called intermediate circuit capacitor, which is connected between the two output terminals of the voltage converter or the power factor correction circuit or between the input terminals of the inverter and also acts as backup capacitance for the voltage converter. If the control gear is now switched on, i.e. the entire circuit arrangement is connected to the power supply system, the intermediate circuit capacitor, i.e. the backup capacitance of the step-up converter, is charged via the converter current path of the step-up converter in a very short period of time via the converter inductor and the boost diode, which results in a very high switch-on current, particularly when switching on happens to take place at the system peak. In the worst case scenario, the capacitor is charged over only one system cycle or even only one system half-cycle. In this case, the system peak is intended to mean the time of the (positive or negative) peak value of the system voltage. The current path via which the backup capacitance is charged is referred to below as the charging current path. The level of the switch-on current can be a multiple (measured up to 200×) of the rated operating current. As a result, the use is restricted to an overcurrent protection since the circuit breaker is triggered in the event of a plurality of devices being simultaneously switched on, although the maximum current of the circuit breaker has by far not yet been reached when the rated current of the devices is taken into consideration.
In order to limit the switch-on current, EP 067 18 67 A has therefore proposed a circuit arrangement which has a parallel circuit including a resistor and a thyristor in the current path of the converter. At the switch-on time of the circuit arrangement, the thyristor is off and only the resistor in the current path is active. The intermediate circuit capacitor is charged slowly and with a low current via said resistor. When the intermediate circuit capacitor has been charged to a predetermined voltage, the thyristor is turned on and bridges the resistor, with the result that the losses are kept low during operation. The circuit arrangement requires many additional component parts, however, and has the disadvantage of high power losses at the switch-on time since there is a power drop which should not be underestimated at the current-limiting resistor.
A circuit arrangement for operating discharge lamps is provided with an input, to which an AC system voltage from a power supply system can be connected, an output, to which at least one discharge lamp can be connected, a backup capacitance, which is arranged between the input and the output, and a switch, which is in a charging current path of the backup capacitance. The circuit arrangement may include a driver configured to clock the switch for a predetermined period of time when the circuit arrangement is switched on for periodically interrupting the charging current path of the backup capacitance.
In the drawings, like reference characters generally refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of various embodiments. In the following description, various embodiments are described with reference to the following drawings, in which:
The following detailed description refers to the accompanying drawings that show, by way of illustration, specific details and embodiments in which the invention may be practiced.
The word “exemplary” is used herein to mean “serving as an example, instance, or illustration”. Any embodiment or design described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments or designs.
Various embodiments provide a circuit arrangement for operating discharge lamps with an input, to which a system voltage from a power supply system can be connected, an output, to which at least one discharge lamp can be connected, and a backup capacitance, which is arranged between the input and the output, and a switch, which is in the charging current path of the backup capacitance, which circuit arrangement requires few additional component parts and only produces low power losses.
Various embodiments provide a circuit arrangement for operating discharge lamps with an input, to which an AC system voltage from a power system can be connected, an output, to which at least one discharge lamp can be connected, a backup capacitance, which is arranged between the input and the output, and a switch, which is in the charging current path of the backup capacitance, with the circuit arrangement clocking the switch for a predetermined period of time when said circuit arrangement is switched on for periodically interrupting the charging current path of the backup capacitance. Clocking of the switch results in advantageous slow charging of the backup capacitance, which results in a significant reduction in the switch-on current.
Slow charging of the backup capacitance of the step-up converter is understood below to mean charging over a period of time which is longer than a system half-cycle. In this case, a predetermined current is not exceeded, i.e. the current drawn by the circuit arrangement has an upper limit during the charging operation. This upper limit can be, for example, the rated current consumption of the circuit arrangement.
The switch represents an additional switch to the obligatory converter switch in the step-up converter if the circuit arrangement has a step-up converter. At best, the switch is switched on in the event of a low instantaneous system voltage. In this case, it can be switched on temporarily in each case at a zero crossing of the system voltage and can be switched off again prior to a subsequent peak voltage of the system voltage. However, it can also be switched on temporarily in each case after a peak voltage of the system voltage, and switched off again at the subsequent zero crossing of the system voltage. Finally, it can be switched on temporarily in each case after a peak voltage of the system voltage, and switched off again prior to a subsequent peak voltage U of the system voltage. In this case it is important that the switch is switched on at a time at which the instantaneous system voltage is greater than the voltage across the intermediate circuit capacitor UC1 by only a small absolute value. By virtue of this measure, the driving voltage is low and the resultant current is low.
The switch-on duration of the switch in this case advantageously increases at the same switch-on time (based on the system phase) from one zero crossing of the system voltage to the subsequent zero crossing of the system voltage. As a result, the capacitor can be charged in uniform steps until the peak voltage Û of the system voltage is reached. By way of example, the switch-off time of the switch is dependent on a voltage increase ΔU of the voltage present across the backup capacitance. In order to increase the capacitor voltage UC1 by the same voltage value ΔU during each charging operation, the switch-off time should be proportional to
The switch is advantageously arranged in series with the backup capacitance, in the event of the presence of a step-up converter between the input terminals of the step-up converter or the power factor correction circuit and the output terminals of the rectifier. This entails the advantage that the switch is only subjected to the ripple current of the capacitor and the losses are thus minimized during operation. The switch can also be arranged in the charging current path, however. As a result, the flexibility in terms of the arrangement of the switch is increased.
In this case, the switch can be a transistor, for example a metal-oxide field-effect transistor (MOS-FET) or a bipolar transistor. However, the switch can also be a thyristor. Electronic switches have the advantage of considerable robustness and operational safety whilst at the same time low costs.
In a further variant of the operation with system-synchronous clocking, the capacitor C1 is not charged further by in each case a fixed voltage ΔU, but the switch-on duration of the transistor Q2 is increased in each case by a fixed time span. The time span by which the switch-on time tC1 of the transistor is changed is therefore fixed, for example tC1=t1 at the first zero crossing, tC1=2*t1 at the second zero crossing etc. Thus, the respective rise in the charging voltage of the capacitor is different since the system voltage follows a sinusoidal function. The criterion for concluding the switch-on current limitation operation can be similar to as in the first variant, with the residual voltage ΔU by which the capacitor voltage UC1 differs from the peak system voltage Û being a predetermined fixed voltage, for example 25 V.
Since the charging of the capacitor C1 during operation with system-synchronous clocking is distributed over a plurality of system half-cycles, the resultant current consumption is correspondingly lower. By virtue of the system-synchronous clocking which begins the charging of the capacitor at a zero crossing of the system voltage, the voltage step between the system voltage and the capacitor voltage is always in a predefined voltage range, and the resultant charging current is correspondingly low. Given a corresponding configuration of the transistor switch-on times, the resultant current consumption can be set in such a way that it is no greater than the current consumption during rated operation of the circuit arrangement.
In this case, ΔU is the voltage by which the capacitor is intended to be charged again. When this time has elapsed, the transistor Q2 is switched off again and the next zero crossing of the system voltage is awaited. This is repeated until the charging voltage UC1 approximately corresponds to the peak system voltage Û. For other frequencies, the formula
can be used, where ω=2*π*fsystem, and in this case f can be f= 50/60 Hz, for example. The charging voltage UC1 of the capacitor should in this case still be slightly lower than the peak system voltage Û since a final charging cycle still takes place as the transistor Q2 is finally switched on. Therefore, as soon as the voltage UC1 present across the capacitor is greater than Û-ΔU, for example, the transistor is switched on permanently, and the circuit arrangement transfers to the normal lamp operating mode.
While the invention has been particularly shown and described with reference to specific embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is thus indicated by the appended claims and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced.
Number | Date | Country | Kind |
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10 2009 019 904 | May 2009 | DE | national |
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Entry |
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English-language abstract of EP 0 671 867 B1. |
English language abstract of DE 36 25 499 C2; Jan. 16, 1992. |
Number | Date | Country | |
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20100277093 A1 | Nov 2010 | US |