Electronic Transformer For A 12V Halogen Lamp CD00003902
User Manual: Halogen Lamp
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APPLICATION NOTE ELECTRONIC TRANSFORMER FOR A 12V HALOGEN LAMP by P. Fichera, R. Scollo 1. INTRODUCTION Lighting that uses halogen lamps is commonly found in residential environments, where it offers a warm light in comparison with that generated by fluorescent tubes, and greater efficiency than conventional filament bulbs. These lamps are available with voltage ratings of 6, 12 or 24 Volts, and so a transformer is needed in order to provide the lamp with a low voltage supply from either 110V a.c. or 220V a.c. mains. They are generally available with power ratings of 50, 75, 100 and 250 Watts. The “electronic” transformer represents an alternative means of power conversion to the more standard iron core, 50Hz transformer technique. The advantages of the electronic transformer compared with the classical solution are: · The output power from the electronic transformer to the lamp can be varied, thus dimming control can be added; · It is possible to include protection against short circuit of the lamp filament; · Weight can be reduced and the construction made more compact; and · Acoustic noise (mains hum) is eliminated. 2. THE ELECTRONIC SOLUTION The topology of the circuit is the classic half-bridge. The control circuit could be realised using an IC (so fixing the operating frequency), but there is a more economical solution which consists of a selfoscillating circuit where the two transistors are driven in opposing phase by feedback from the output circuit. 3. CIRCUIT DESCRIPTION The line voltage is rectified by the full-bridge rectifier, generating a semi-sinusoidal voltage at double the line frequency. The diac starts to conduct during each cycle, starting the half-bridge oscillation. The turn-on of the diac can be varied by modifying the time constant of the RC network formed by R and Figure 1. Electronic transformer for 12V Halogen Lamp R C2 T'1 TR1 T1 D C1 C3 T''1 AN528/0999 TR2 1/4 APPLICATION NOTE C1. This can be varied to provide a lamp dimming feature. Once the cycle has started, the diode D maintains the voltage across C1 at a value less than the diac conduction threshold voltage, so the transistor can switch off. The frequency of oscillation depends mainly upon the size and maximum flux density of the core used in the feedback transformer, and the storage time of the transistors. When the cycle has started, the current in the feedback transformer increases until the core saturates. At this point the feedback drive of the active transistors is therefore removed, and, once its storage time has passed, it turns off. In this application the oscillation frequency would be around 35kHz, generally around ten times the natural frequency of the circuit. The dependence upon the storage time is minimised by the RC network at the base of the transistor, which increases the rate of charge extraction from the base at turn-off. The network also serves to decouple the base from the oscillation caused by the base transformer at turn-off, preventing spurious turn-on of the device. The anti-parallel diodes allow current to flow when devices are off. 3.1 Short Circuit Protection Figure 2 shows a circuit with circuitry to protect against a short circuit of the load added (note - some components have been removed for clarity). The circuit operates as follows. A short circuit of the lamp will cause an excessive current to flow through the transistors, which will eventually cause them to overheat and be destroyed. However, this current will also cause the voltage across RE to increase. This causes transistor TRS to turn on, which in turn prevents the diac from triggering the circuit at the start of each cycle. RS and CS serve to delay the turn-on of the transistor, preventing the protection being triggered during the inrush phase at the turn on of the lamp (when the lamp filament is cold, it has a very low resistance, causing a large but brief current to flow through the transistors at turn-on. This resistance increases when the lamp heats up, and the current through the transistors falls to its steady-state value). Diode DS prevents the small-value resistor RE disrupting the operation of the filter. After a short time (a few operating cycles), the capacitor CS will become discharged and so will be unable to keep TRS turned on, and the circuit will attempt to restart itself. If the fault condition still Figure 2. Transformer with short-circuit protection added (shown shaded grey) TRS RS CS 2/4 DS RE APPLICATION NOTE exists, the protection will be re-triggered after a short time. In this way the circuit limits the energy dissipated by the transistors. It should be noted that the transistor must be robust enough to withstand the fault condition while the short circuit protection reacts - that is to say devices with a large RBSOA must be used. 4. TRANSISTOR SELECTION Because of the tight cost constraints and the voltage range of this application, the bipolar is the usual choice of transistor. The voltage and current ratings of the power devices used must be selected based on the circuit topology, the required output power and the frequency of operation. 4.1 Voltage rating The required voltage rating of the devices is defined by the half-bridge topology. Supplying the circuit with 220V RMS A.C. mains, calculating peak value, and adding a safety margin, gives a maximum supply voltage VCC of: VCC(max) = = ≈ 220V x √2 + 10% 310V + 10%. 350V. To this figure must also be added the overvoltage generated by the input filter at turn-off. In practice, devices are used with a rating of: VCE(max) = 450 - 500V IC(peak) = 0.64A As stated above, when the circuit is first turned on, the low initial resistance the lamp filament causes a large current to flow through the transistors. This current can be up to ten times the current in the steady state, and the devices must be selected to withstand this. In this example then it is recommended that the device used is bipolar transistor, rated at 450V and around 7A. An example is the BUL38-D, which also incorporates an integrated anti-parallel diode. 4.3 Storage and fall times The fall time, tfall, of the transistors influences the losses of the circuit, while the storage time, ts, is important as it affects the switching frequency of the converter. The nature of the processes used to produce bipolar transistors means that the storage time between batches of transistors may vary considerably. The transistors used must be manufactured, tested and selected to have storage times within certain limits. Transistors with too large a storage time may cause the circuit to oscillate below the operating limits of the output transformer, causing saturation of the core towards the end of each cycle. This will cause a spike in the collector current of the transistors every cycle, which will eventually cause them to overheat and be destroyed. 4.2 Current rating 5. POWER FACTOR CORRECTION The nature of the half-bridge topology is such that in normal operation, half the supply voltage is dropped across each device, so from the above figures VCE in the steady state is 310V /2, 155V. Hence the collector current in the steady state can be calculated using: 2. POUT As the capacitor at the input of the circuit is relatively small, there is little deformation of the input current waveform. However, this type of circuit generates a certain amount of electro-magnetic interference, due to the high frequency source that feeds the resonant network, and so a suitable filter must be inserted in the circuit before the rectifier bridge to prevent this interference being fed back to the mains. This filter must satisfy VDS and UL norms concerning maximum RFI levels, clearance and creepage distances and the frequency response of the filter. Vmains CONCLUSION POUT = VCE(RMS) = IC(RMS) = IC(RMS) . VCE(RMS) 1/2 . Vmains IC(RMS) = IC(peak) IC(peak) = 2 . √2 . POUT = 2 . √2 . 50W √2 Vmains 220V Electronic transformers can offer an economic, simple and compact alternative to the traditional 50Hz transformer. This technique is particularly useful in halogen lamp applications because of the short circuit protection, reduced weight, absence of acoustic noise and the possibility of including a dimming facility. 3/4 APPLICATION NOTE The simple general circuit shown and the guidance given in choosing a suitable transistor should provide a useful starting point for developing more specific applications. Electronic Transformer Design-in Guidelines Type Vcew (V) Vces/Vcev (V) Ic (A) Ptot (W) Package BUL39D* BUL38D* BUL49D* BUL58D* BUL59 BUL67 BUL510 BUL89 BUL810 400 450 450 450 400 450 400 450 450 850 800 850 850 800 700 1000 850 1000 4 5 5 8 8 10 10 12 15 70 80 80 90 85 100 100 110 125 TO-220 TO-220 TO-220 TO-220 TO-220 TO-220 TO-220 TO-220 TO-218 Typical Application up to 50W up to 75W up to 75W up to 105W up to 105W up to 150W up to 150W up to 250W up to 300W *Integrated freewheeling diode Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specification mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a trademark of STMicroelectronics 1999 STMicroelectronics - Printed in Italy - All Rights Reserved STMicroelectronics GROUP OF COMPANIES Australia - Brazil - China - Finland - France - Germany - Hong Kong - India - Italy - Japan - Malaysia - Malta - Morocco Singapore - Spain - Sweden - Switzerland - United Kingdom - U.S.A. http://www.st.com 4/4
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File Type : PDF File Type Extension : pdf MIME Type : application/pdf PDF Version : 1.3 Linearized : No Page Layout : SinglePage Page Mode : UseNone Page Count : 4 Producer : Acrobat Distiller Daemon 3.0 for Solaris 2.3 and later (SPARC) (via http://big.faceless.org/products/pdf?version=2.6.5) Creator : C2 v2.1.0 build 004 Title : Electronic transformer for a 12V halogen lamp Keywords : Technical Literature, 3707, Product Development, Specification, Application note, BUL38D, Light Dimmer Modify Date : 2010:03:23 15:39:16+01:00 Subject : - Create Date : 1999:09:24 15:44:34 Author : STMICROELECTRONICSEXIF Metadata provided by EXIF.tools