DE4441141A1 - Mains-fed ballast feeding load with pulsed DC e.g. for compact fluorescent lamps - Google Patents

Abstract

A ballast unit transforms mains AC into DC using a rectifier circuit followed by a choke plus a bank of condensers and diodes to supply the load. The bank comprises two condensers (c1,c2) and three diodes(d1 to d3). The condensers are each in series with one diode and are in parallel branches, discharging into the load (3) while the pulsating input voltage is below half its peak value. The total capacitance of the condensers is about five times smaller than the capacitance of a charging condenser found in conventional circuits and they have only half the conventional breakdown voltage. If the instantaneous mains voltage lies above half its peak value, the load is fed directly from the mains.

Description

The subject of the present invention is a ballast with AC / DC conversion according to the preamble of the claim 1. Such ballasts are used for. B. as ballasts used to power compact fluorescent lamps or also for the power supply of other electrical Devices with a (more or less) pulsating or fluctuating DC voltage can be supplied like e.g. B. televisions, radios, amplifiers and all Devices in the field of electronics, disposable, two path or bridge rectifier circuits, or span voltage multiplier circuits included.

The invention therefore relates to a power supply unit for feeding any electrical consumer that pulsate with a the or fluctuating DC voltage can be fed.

In the previously known power supplies, which according to the same direction of the input AC voltage a charging capacitor have only a power factor of about 0.5 reached. This is unsatisfactory because of the power line is loaded with current peaks, which leads to deformation of the Sine network curve leads.

British Patent 2 115 627 A is one Arrangement for power factor correction of a power supply  become known which is an improvement in performance factor realized in that the pulsating equal voltage present at the output of a rectifier circuit, is compensated by a counter voltage and thereby in a DC voltage is converted. To compensate for the pulsating DC voltage is inductive via a Current transformer a voltage is decoupled from the load circuit, which is led to a rectification arrangement which the voltage opposite the pulsating input voltage generated. The disadvantage here is that inductive elements must be used to return the tax voltage on the input circuit to enable what with relatively high costs and high space requirements.

However, the correct functioning of this circuit is to doubt because they are in the form described Stabilization needed. Because of the use of the feedback principle, operation is relatively critical because the Compensation for only a very specific load adjustment works or only for a certain working point works. For this reason, a stabilization circuit to be provided for large deviations of the Avoid output voltage.

US 5,010,277 describes a converter circuit in which a capacitive feedback feedback signals is described.

This circuit has the disadvantage that a Stabilization of the working point due to the feedback Signal is necessary. The output voltage must also be here be stabilized speaking.

However, this involves an increased circuit outlay.

The invention is therefore based on the object To further develop the power supply of the type mentioned at the beginning that with a relatively small footprint a cheap performance factor of the power supply is reached.

To achieve the object, the invention is completed by characterized the technical teaching of claim 1.

The essence of the invention is that in principle a capacitive or inductive feedback of a signal is dispensed with and instead by a capacitor Diode arrangement is ensured that the at the output of the Rectifier circuit, pulsating DC voltage voltage does not fall below about half the peak value.

So long as the instantaneous value of the mains voltage is larger as the half of the peak value is the following Consumers fed directly from the network. E.g. behaves the converter of a fluorescent lamp approaches wise as a load with constant current characteristics.

When the mains voltage reaches the peak value, the capacitors connected in series in series via a diode loaded. Because the series connections of the two capacitors a capacity of only z. B. 0.5 microfarads the charge current peak is relatively small.

The advantage here is that you have relatively small drawer capacitors can be used because the bridging Voltage gap is short. The space requirement of the circuit according to the invention very small.

During the short time when the mains voltage is less than that Is half of the peak value of the input voltage, the Converter fed from the capacitors, which are now over  two diodes are parallel to each other. During this time the mains current is zero. So the capacitors have that Task of continuing to supply the electricity consumer with electricity, also during the mains voltage zero crossing.

This type of feeding a consumer makes a lei performance factor of 0.9, what with the conventional Circuits with only one charging capacitor was not possible. With these circuits, there was only one power factor of about 0.5 reached.

Another advantage of the invention is that on an inductive or capacitive feedback of a signal can be dispensed with can, resulting in a stable operating point of the circuit results. The circuit is therefore relatively insensitive against fluctuations in the dimensioning of the components and just as insensitive to temperature fluctuations and against fluctuations in the mains input voltage.

In a development of the present invention, it is provided that the circuit according to the invention still with can be provided with a dimmer. The dimmer is the subject another application by the same inventor.

However, the present invention is not based on the existing limited to being a dimmer; the dimmer can accordingly also dropped.

Another advantage of the present circuit is in that for the respective capacitor of the invention according to the capacitor cascade only half the voltage strength is required compared to a single charging con capacitor. The capacitors can also be used accordingly can be designed smaller.  

The subject matter of the present invention provides not only from the subject of each patent sayings, but also from the combination of the individual Pa claims among themselves. All in the records, one finally the summary, disclosed information and Features, in particular that shown in the drawings spatial training are bean essential to the invention speaks to the extent that they face each other or in combination the state of the art are new.

In the following the invention is based on an application example of a compact lamp explained in more detail. The same The same considerations apply to all electronic devices with power supply circuits mentioned at the beginning. Here go further from the drawings and their description features and advantages of the invention essential to the invention forth.

Show it:

Fig. 1 basic circuit of a power supply circuit.

Fig. 2 power supply device.

Fig. 3 Voltage diagram between points A and B of the circuit of FIG. 2.

Fig. 4 current diagram of the input current.

With reference to FIG. 1, the basic Schaltungsein be zelheiten a basic circuit explained.

On the network comes via appropriate interference suppression rectifier 2 , at the output of which the capacitor cascade 1 is arranged.

At the output of the capacitor cascade 1 there is a supporting capacitor 19 for the consumer 3 , which here contains a converter with a lamp.

This capacitor 19 is drawn out of the block diagram of the consumer 3 only for drawing reasons.

The supporting capacitor 19 is dimensioned so small that it does not impair the function of the capacitor cascade 1 .

The function of the capacitor cascade 1 will now be explained in more detail with reference to FIGS. 1 and 3.

The line voltage is converted via the line rectifier 2 into a pulsating DC voltage, which is present at points A and B. As long as the instantaneous value of the mains voltage is greater than half the peak value 20 of the mains supply voltage, the following consumer 3 is fed from the mains.

Using the example of a compact lamp with converter, consumer 3 behaves approximately like a constant current sink.

When the mains voltage reaches the peak value 20 , the capacitors C2 and C3 are charged in series via D2. Since the series connection of C2 and C3 has a capacity of only 0.5 microfarads, the charging current peak is relatively small.

The following applies to the representation in FIG. 3:
The voltage curve between points A and B begins at the zero crossing of the mains voltage, the voltage in position 4 on the capacitor cascade being approximately half the mains voltage. Starting from position 4 , a curve branch 6 extends obliquely down to position 5 . This curve branch 6 corresponds to the discharge of the capacitor cascade by the consumer 3 (converter with lamp).

From position 5 , the supply network voltage has reached a value which overlaps with the discharge of the capacitor cascade 1 , so that the curve branch rises from position 5 and follows the supply network voltage, up to a peak value of 20 .

In the peak value 20 , the capacitor cascade from the capacitors C2 and C3 is recharged via the diode D2. In this functional state, the two capacitors are connected in series.

Beyond the peak value 20 , the rectified voltage at the output of the capacitor cascade follows the supplying mains voltage to position 12 , which in turn corresponds to approximately half the peak value of the mains voltage. The power supply voltage now drops in the form of the indicated branch 7 to zero, but this does not apply to the voltage across the capacitor cascade.

From position 12 the capacitor cascade 1 takes over the feeding of the converter 3 , whereby the curve branch 6 will run through until the position 13 is reached.

A new cycle begins at position 13 and has been described from point 5 .

As soon as the consumer 3 is disconnected, the circuit comes into no-load operation and instead of the curve branch 6 there is a curve branch 8 , which means that the voltage of a capacitor cascade is kept at half the peak value of the mains voltage. The advantages of the circuit according to the invention compared to the prior art will now be explained with reference to FIG. 4.

In FIG. 4, the current at the power input, so that is shown at the input of the power rectifier 2 over time. Different current profiles are compared, curve 14 corresponding to the current profile of the capacitor cascade 1 , while curve 15 corresponds to a conventional compact fluorescent lamp with a power factor of approximately 0.54 and a power consumption of approximately 11 watts. The curve 16 applies in the event that the capacitor cascade 1 is still connected to a dimmer circuit.

Curve 15 thus corresponds to a circuit which only has a charging capacitor at the input of a converter. It can be seen that at position 21 the voltage peak value is used for recharging the charging capacitor, which has the disadvantage that a high current peak (peak 17 ) suddenly arises.

As a result, the mains current becomes uneven from the mains taken.

In contrast to this, curve 14 shows the current draw according to the invention, whereby it can be seen that already at position 22 a current flows which results from the load current, the capacitor cascade being recharged in tip 18 . This tip 18 is very small because the capacitors C2 and C3 can be kept very small.

This results in the relatively uniform current draw from the supply network over a long period of time, because the current draw only ends at position 23 , while according to the prior art the current draw already ends at position 24 .

Referring to Figs. 2 and 3 can still be mentioned that the compact lamp is dimmable, the lamp is intermittently turned on and off during dimming.

The load is switched on between positions 10 and 11 , while in the remaining areas the capacitor cascade 1 is idle. The curve branch 8 then also applies because the rectifier circuit is temporarily idle. The current consumption from the mains during dimming operation is shown in curve 16 .

In Fig. 2 the same conditions apply in principle as in Fig. 1, ie there is the same capacitor cascade 1 and it can be seen how the switching of a converter can be carried out.

The circuit elements of this converter belong to the stand the technology and therefore require no further explanation.

It is only referred to the presence of dimming logic, which is supported in its function by the capacitor cascade 1 .

Claims (5)

1. Ballast with AC / DC conversion, consisting essentially of a rectifier circuit and subsequent capacitor circuit for supplying a load, characterized by a capacitor-diode arrangement ( 1 ) provided after the rectifier circuit ( 2 ), consisting of at least two capacitors (C2 , C3) and at least three diodes (D1 to D3). 2. Ballast according to claim 1, characterized in that the capacitors (C2, C3) are each parallel to one another via the diodes (D1, D3) and are discharged via the consumer ( 3 ) while the rectifier ( 2 ) coming from pulsating input voltage is in the range below half its peak value ( 20 ). 3. Ballast according to one or more of the claims 1 to 2, characterized in that the total capacitance of the capacitors (C2, C3) z. B. the A factor of five is less than the capacity of one Conventional circuits provided charging capacitor. 4. Ballast according to one or more of the claims 1 to 4, characterized in that the capacitors (C2, C3) only about half the voltage have to have strength than a conventional one Circuits used charging capacitor. 5. Ballast according to one or more of claims 1 to 4, characterized in that the capacitors (C1, C2) are dimensioned such that the voltage above the points (A, B,) of the capacitor diode arrangement ( 1 ) is only up to falls below about half the peak value ( 20 ) of the input voltage.