DE19546874A1 - Electronic power supply for LV halogen lamps - Google Patents

Abstract

A power supply has a full wave rectifier fed from the mains followed by a flyback converter which is formed by a transistor push/pull stage whose output goes to a transformer and whose frequency is higher than that of the mains. The converter has two transistors (t2,t3) whose collector-emitter paths are in series and at the output, the unsmoothed direct voltage lies across two condensers (c7,c8) in series. Between the connecting nodes in each of these paths is a transformer's primary winding (w1). The base-emitter paths of the transistors are controlled by the transformer's secondary winding(w2,w3) through parallel RC circuits.

Description

The invention relates to an electronic power supply device according to the Preamble of claim 1.

Such power supply devices are generally known. The conventional one Power supplies used transformers can be compared such transformers that are used for step-down transformation at mains frequency are used, have relatively small spatial dimensions, because the Frequency of the flyback converter is relatively high compared to the network frequency and therefore small ferrite cores can be used for the transformers

The object of the invention is the effort for To reduce power supply device of the type mentioned and To further improve the efficiency of the power supply device.

This object is achieved by the features of claim 1.  

With such a power supply device do not need expensive Smoothing capacitors are used. Furthermore, the parallel RC elements in the control circuits of the transistors have a faster charge carrier discharge reached at the bases of the transistors when they are switched off, so that the Dependence of the flyback converter frequency on the storage time of the transistors is reduced. These parallel RC elements also reduce the power loss of the Transistors, so that the efficiency of the power supply device is increased. In this way, an efficiency of 95% can be achieved. In addition, with the Claim 1 marked flyback converter achieves a smooth start.

So that the flyback converter can be protected against overload, a a further embodiment of the invention in the emitter circuit of the second transistor Emitter resistor arranged, of which a voltage to influence the Voltage at the third capacitor is derived in the sense of a reduction.

An expedient design of the overload protection circuit provides according to the Invention before that to the emitter resistor via a rectifier and Smoothing element connected the base-emitter path of a third transistor whose collector-emitter path is parallel to the third capacitor.

The known power supply devices are mostly in plastic housings housed, the terminal strips outside the housing are arranged and the connections are therefore not protected against contact. In order to remedy this situation, the Invention the electrical connections of the power supply device within the Arranged housing and only via guide sleeves molded onto the housing made accessible to screwdrivers.

The invention will now be explained in more detail using an exemplary embodiment. It demonstrate:  

Fig. 1 shows a circuit arrangement for an electronic power supply unit,

Fig. 2 shows a section through a housing shell for the power supply device,

Fig. 3 is a view of the upper housing part of the bottom shown in Fig. 2,

Fig. 4 shows a section through the lower housing part for the power supply device (along the line AA in Fig. 5) and

Fig. 5 is a plan view of the lower housing part shown in Fig. 4.

The power supply device specified in the circuit arrangement according to FIG. 1 serves to supply halogen lamps from the AC network and is preferably designed as a ballast for such lamps.

At input connections a1, a2 which can be connected to the AC network is via a filter C1, L1, C2 tuned to the flyback converter frequency Bridge rectifier D1 connected. This filter prevents tension are coupled into the AC network at the flyback frequency. The The output voltage of the bridge rectifier D1 is not smoothed. To the The output of the bridge rectifier D1 are collector-emitter Routing two transistors T2, T3 and two capacitors in series C7, C8 turned on, one in the emitter circuit of transistor T3 Emitter resistance R12 is. Between the common connection point this Collector-emitter paths and the common connection point of these Capacitors are the series connection of a winding W1 of a transformer L2 and a winding of another transformer L3, both of which  Transformers are preferably equipped with ferrite cores. Output windings of the transformer L3 are at output terminals a3, a4 connected with which halogen lamps can be connected. The base emitter Routes of the transistors T2, T3 are each by a winding W2, W3 Transformer L2 via a respectively assigned parallel RC element R5, C5 or R6, C6 and a current limiting resistor R3 and R1 controlled, the Base-emitter path of transistor T2, a resistor R7 is in parallel and the Series connection of the base-emitter path of the transistor T3 and that Emitter resistor R12 is a resistor R8 in parallel. The control circuit of the second transistor T3 is connected to a third capacitor C3 via a diac D3 connected via a resistor R2 to the Bridge rectifier output is connected. The collector of transistor T3 is via a diode D2 with the common connection point of resistor R2 and the capacitor C3 connected.

At the output of the bridge rectifier D1 is a varizer R1 connected to the flyback converter from overvoltage peaks AC grid protects. Furthermore, the collector-emitter path of the Transistor T2 a free-wheeling diode D5 and the series circuit of the collector Emitter path of the transistor T3 and the emitter resistor R12 one Free-wheeling diode D6 connected in parallel. These freewheeling diodes protect the transistors T2, T3 before overvoltages when switching off.

To the emitter resistor R12 is connected via a rectifier and smoothing element D4, R9, C4 and a current limiting resistor R10 the base-emitter path a third transistor T1 is connected, the collector-emitter path the third capacitor C3 is in parallel and on its base-emitter path Resistor R11 is connected. This circuit part described last serves as overload protection for the transistors T2, T3 in the event of a short circuit to the Output connections a3, a4.  

The mains voltage is converted into a DC voltage with the bridge rectifier D1 rectified from sinusoidal half-waves with twice the mains frequency. If the Voltage on capacitor C3 the ignition voltage, for example of 34 V, the Diac has reached D3, the transistor T3 is turned on, so that Vibrations can start with a frequency of about 27 kHz. Here the transistors T2, T3 are in push-pull from the windings W2, W3 controlled. The collector current of transistor T2 flows during one Half wave through the capacitor C7, the input winding of the transformer L3 and the winding W1 while the collector current of the transistor T2 during the another half wave in the opposite direction via winding W1, the input winding of the transformer L3 and the capacitor C8 flows.

The ignition timing of the Diac D3 can with the time constant of the RC element R2, C3 can be varied so that you can dim the halogen lamps with a potentiometer could. After the oscillation cycle has started gently, the diode D2 provides for the fact that the voltage on capacitor C3 does not match the ignition voltage of diac D3 significantly exceeds, so that the transistor T3 can turn off again.

The frequency of the blocking oscillator mainly depends on the size and the maximum flux density of the transformer L2 and the storage time of the transistors T2, T3 from. When the vibration has started, the current in the transformer rises L3 to core saturation. When core saturation is reached, the base current of the switched on transistor T2 or T3 to zero, and this transistor switches after its storage time. The dependence of the flyback converter frequency on the Storage time of the transistors T2, T3 is by the parallel RC elements R5, C5 and R6, C6 minimized. These links accelerate the charge carrier outflow to the Bases when turning off these transistors. Accordingly, the Flyback converter frequency can be kept substantially constant.

In the event of a short circuit at the output connections a3, a4, the  Collector current of the transistors T2, T3 very strongly. The strong collector current of the transistor T3 causes a high voltage drop across the emitter resistor R12, whereby the capacitor C4 is charged. When the tension on Capacitor C4 becomes so large that the response threshold of the base-emitter path of the transistor is exceeded, this transistor is controlled conductive. In order to this transistor prevents the diac D3 from igniting at the start of the cycle. Of the Capacitor C4 is then across the control path of transistor T1 and Slowly discharge resistors R10, R11 until the voltage is below the Base threshold voltage of transistor T1 drops. This is followed by a new beginning of Oscillation cycle. If the output ports a3, a4 still are short-circuited, the locking process begins again.

In Figs. 2 to 5 a plastic housing of an upper housing part 10 (Fig. 2, 3) and a lower housing part 20 (Fig. 4, 5), respectively. The device shown in FIG. 1 can be installed in this very small housing in such a way that the connections a1 to a4 cannot be touched. The housing parts 10 , 20 have a box-shaped structure and can be firmly connected to one another by means of snap connections and / or by means of rivets. At the ends of the upper housing part 10 sleeves 11 for access to the connections a1, a2 and sleeves 12 for access to the connections a3, a4 and other similar connections are molded. Through the sleeves 11 , 12 , a screwdriver can be guided to fasten the lead wires, which can be passed through bushings 13 , 14 of the upper housing part 10 for this purpose. The upper housing part 20 has at the ends each a two fastening holes fastening tab 21 and 22 , which is designed so that it can be broken off if necessary.

Claims (4)

1.Electronic power supply device for feeding low-voltage consumers, in particular halogen lamps, from the AC network with a double-wave rectifier fed from the network and a flyback converter connected to this rectifier, which is formed from a transistor push-pull stage with a transformer located in its output and whose frequency is significantly higher than the network frequency is characterized by a flyback converter with the following features:

• a) Collector-emitter paths of two transistors (T2, T3) and two capacitors (C7, C8) in series are connected to the output of the full-wave rectifier (D1) which emits an unsmoothed DC voltage,
• b) there is a winding (W1) of the transformer (L2) between the common connection point of these collector-emitter paths and the common connection point of these capacitors,
• c) the base-emitter paths of the transistors (T2, T3) are controlled by a winding (W2, W3) of the transformer (L2) via an associated parallel RC element (R5, C5; R6, C6) and
• d) the control circuit of the second transistor (T3) is connected via a diac (D3) to a third capacitor (C3) which is connected to the full-wave rectifier output via a resistor (R2).

2. Power supply device according to claim 1, characterized, that an emitter resistor in the emitter circuit of the second transistor (T3) (R12) is arranged, of which a voltage to influence the Voltage at the third capacitor (C3) in the sense of a reduction is derived. 3. Power supply device according to claim 2, characterized, that to the emitter resistor (R12) via a rectifier and Smoothing element (D4, R9, C4) the base-emitter path of a third Transistor (T1) is connected, the collector-emitter path of the third capacitor (C3) is in parallel. 4. Power supply device according to one of claims 1 to 3 for installation in a plastic housing, characterized in that the electrical connections (a1 to a4) of the power supply device are arranged within the housing ( 10 , 20 ) and only via guide sleeves ( 11 , 12 ) are accessible to screwdrivers.