CH684510A5 - Through a battery without interruption based switching power supply. - Google Patents

Description

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description

The invention relates to a switching power supply, which is supported by a battery without interruption, according to the preamble of claim 1.

The operation of numerous electronic devices, e.g. of computers, requires a secure, uninterrupted supply. This condition cannot be met by the public network. Rather, special power supply systems are required for this purpose, which allow bridging of short switching interruptions or even power outages lasting for hours.

From GB 2 120 474 A, for example, a corresponding switched-mode power supply is known which, in the event of a power failure, switches continuously to a backup battery as the power supplier. This switching power supply has two separate primary circuits which are connected to two separate primary windings of a single transformer. On the secondary side, several output circuits are provided. The regulation is carried out by means of pulse width modulation, the control signal being fed to the two primary circuits in parallel. The switchover between the primary circuits, which are thus controlled synchronously, necessarily takes place on the basis of the respective voltage conditions in these circuits, with four isolating diodes participating.

Another switching power supply for military applications is known from WO 92/05614, which can bridge interruptions in very short-term transients with the aid of a charged capacitor. This switching power supply also has a single transformer with two primary-side windings, which are assigned to normal operation or bridging operation. A charging circuit is also provided, which is connected to an associated winding of the transformer and charges the capacitor during normal operation.

The first-mentioned font does not indicate a possibility of charging the required battery. The arrangement of the second font is relatively complex and hardly suitable for civil applications. The type of capacitor charging constantly causes alternating energy flows between different states, which does not allow the use for charging high-capacity batteries.

It is therefore the object of the invention to provide an inexpensive, fail-safe switching power supply for predominantly civil applications, in which a charging circuit is included for charging a larger backup battery during normal operation on the supply network.

The solution to this problem is given by the characterizing part of claim 1. The dependent claims provide embodiments of the invention.

The solution according to the invention is comparatively simple and allows inexpensive uninterruptible switching power supplies to be manufactured. The solution thus perfectly fulfills the conditions of the task specified at the beginning.

The invention is described in more detail below with reference to four figures, for example.

Show it:

Fig. 1 - basic block diagram of an under-supported switching power supply;

Fig. 2 to 4 - Detailed circuit diagrams of corresponding switching power supplies.

1 shows the block diagram of an uninterruptedly supported switched-mode power supply 11. This comprises a single transformer 13 with, for example, four windings 14-17, two primary-side converter modules 21, 22, two isolating diodes 25, 26, two secondary-side output modules 31, 32, and a controller 35 and a charging circuit 41.

The first converter module 21 is connected on the input side via a separate rectifier circuit 27 and via the isolating diode 25 to the general single-phase or multi-phase AC network, e.g. to a three-phase network 50 Hz, 400 V. The output voltage of the rectifier circuit 27 is buffered via a smoothing capacitor 28. On the output side, the first converter module 21 is connected to the two poles of the first winding 14 of the transformer 13.

The second converter module 22 is connected in an analogous manner on the input side via the second isolating diode 26 to a DC battery 29, e.g. a NiCd battery connected to which a buffer capacitor 30 is connected in parallel. On its output side, the second converter module 22 is connected to the second winding 15 of the transformer 13.

On the secondary side of the transformer 13, the further windings 16, 17 are individually connected to two independent output modules 31 and 32, respectively. The number two corresponds to the selected example of four windings 14-17, with one, three or more output modules being possible instead.

The regulator 35 is connected with its voltage sensor to the output lines 33 of the output module 32 and with its transmitter via a line 36 to the control inputs of both converter modules 21, 22. It works as a pulse width modulator and controls the converter modules 21, 22 synchronously. The entire control loop is a reverse regulator for the output voltage U2 at the output 33 of the second output module 32. The output voltage U1 at the first output module 31 and possibly further output voltages are also loosely coupled via the transformer 13.

Finally, the charging circuit 41 is connected with its input 42 to the two poles of the second winding 15 and with its output 43 to the poles of the battery 29. The charging circuit 41 is thus antiparallel to the series connection of the second isolating diode 26 and the second converter module 22, i.e. in parallel as a circuit, but in opposite directions in the current direction. The charging circuit 41 preferably has a charge controller (not explicitly shown) and a control line 65.

Each converter module 21, 22 forms, together with the output module (s) 31, 32, a so-called flux converter. Since both converter modules 21, 22 are constantly controlled in parallel and synchronously by controller 35, they basically work in parallel. Due to the effect of the isolating diodes 25, 26

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However, only the converter module 21, 22 draws energy from its input connection, i.e. from the rectifier circuit 27 or from the battery 29, the internal voltages of which are higher than the corresponding voltages of the respective other converter module 22, 21. In this way, one of the converter modules 21, 22 acts as a “stand-by” module, which takes over the energy supply function at any time and without interruption as soon as the voltage conditions described reverse.

In normal operation, the voltage conditions are such that the AC network supplies the required energy. If the voltage breaks down in this network for any reason, the battery 29 immediately takes over the supply of energy until the mains voltage is re-established. This ensures the desired freedom from interruption seamlessly.

The charging circuit 41 can now be designed either as a secondary-side step-up converter or as a discontinuously operating step-down converter. In both cases, decoupling elements ensure that the charging circuit 41 only works when the first converter module 21 supplies the energy. In this case, the second winding 15 of the transformer 13 serves as a secondary winding, via which energy flows to the battery 29. If, on the other hand, the second converter module 22 supplies the energy, then the second winding 15 serves as the primary winding of the transformer 13 and the charging circuit 41 is blocked. The control line 65 mentioned can be used to control these decoupling elements.

The rectifier elements of the charging circuit 41 operate, depending on the given voltage conditions, more or less using the given half-waves. If only the voltage peaks are detected in the manner of a peak value rectifier, then a downstream linear regulator can advantageously be provided, which smoothes and linearises the resulting pulsating direct current.

It was mentioned that each converter module 21, 22 together with the output module (s) 31, 32 form a flux converter. As a flux converter, single-switch single-ended flux converters are preferred when the power requirement is low and two-switch common mode flux converters are used when the power requirement is higher. However, push-pull flux converters can also be provided, e.g. with conventional full bridge or with full bridge operated with «phase shift» control.

It is further advantageous if the two converter modules 21 and 22 are constructed identically or at least essentially identically. However, this is not an absolute must; in principle, different converter modules 21 and 22 can also be used. The same applies to the output modules 31, 32 if more than one such module is used.

The following figures now show detailed exemplary embodiments of switching power supplies 11 in which different flux converters are used.

FIG. 2 shows a detailed circuit diagram of a first switching power supply 11 corresponding to the described block diagram of FIG. 1. The first converter module 21 comprises a switch controlled by the line 35 from the regulator 35, in particular a transistor 51, which is connected in series with the winding 14. It also includes a diode 52 and a zener diode 53, which bridge the winding 14 in series with the isolating diode 25.

In the same way, the second converter module 22 comprises a transistor 55 controlled via the line 36, which is connected in series with the second isolating diode 26 and the winding 15.

The charging circuit 41 is designed as a discontinuously operating step-down converter and comprises a diode 61, a freewheeling diode 62 and a choke 63. The battery capacitor 30 serves as the charging capacitor. Furthermore, an actuator in the form of a (third) transistor 64 is provided, which is in series with the diode 61 is located and can be controlled via the control line 65, in particular by the charge controller mentioned.

The only output module 31 in FIG. 2 comprises, in a known manner, a charging diode 71, a freewheeling diode 72, a choke 73 and a capacitor 74. The output voltage U1 is present at its output and is supplied to the controller 35 as the actual value of the control circuit mentioned .

The switching power supply 11 described forms two complementary and cooperating one-switch single-ended flux converters with a demagnetizing circuit, the transistors 51 and 55 forming the associated switches. The construction of the switching power supply is simple and preferably suitable for an output power of approximately 100 to 200 W.

FIG. 3 shows a detailed circuit diagram of a second switching power supply 11. The upper part of FIG. 3 is identical to the circuit diagram of FIG. 2 and shows details of the first converter module 21 and the output module 31. In the lower part of FIG the line 36 controlled transistor 55 the second converter module 22nd

The charging circuit 41 comprises two rectifier diodes 67, 68 which are connected to the two poles of the winding 15 and together to the charging inductor 63. Another diode 69 connects the charging inductor 63 to the isolating diode 26. The control transistor 64 is finally connected between the charging inductor 63 and the winding 15.

The special feature of the switching network part 11 according to FIG. 3 compared to that of FIG. 2 is that the chokes 63 and 73 are partially magnetically coupled. Since, after the charging process has ended, no more current may flow into the battery 23 via the diode 69, the voltage of the second winding 15, which is higher than the voltage on the capacitor 30 when the switch 51 is switched on, is below the voltage of the capacitor 30 by this coupling reduced, thereby preventing an undesirable current flow.

4 shows a detailed circuit diagram of a third switching power supply 11 for preferably output powers up to 1 kW. In this version, two transistors 81, 82 and 83, 84 are used in common mode in both converter modules 21, 22,

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which enables the higher performance mentioned. To reduce switching peaks, four diodes 91-94 are provided, each of which is connected in parallel to the series connection of one of the transistors 81-84 and one of the windings 14 and 15.

The invention allows a number of further variants and additions. Of these, it should be specifically stated that instead of the switching transistors 51, 55, 64, 81-84, other controllable switches can also be used, e.g. MOSFETs.

Claims (8)

Claims 1. Switching power supply (11) supported without interruption by a charge store, - With a single transformer (13) comprising several windings (14-17), - With a primary-side, connected to an AC network and a first of these windings (14), first converter module (21), - With a primary-side, connected to the charge storage and a second of these windings (15), second converter module (22), - With at least one output module (31, 32) on the secondary side connected to a further one of these windings (16, 17), and with a reverse control loop on the basis of a pulse-width modulation for the synchronous control of both converter modules (21, 22), characterized in that - That the charge storage is a battery (29), a capacitor (30) is connected in parallel, - That a charging circuit (41) for charging the battery (29) is provided, which charging circuit is anti-parallel to the second converter module (22) to the battery (29) and to the second of the windings (15), and - That two separating diodes (25, 26) are provided, which are inserted between the battery (29) and the respectively associated converter module (21, 22) for separating the effect of the two converter modules (21, 22) depending on the one in each case Tensions. 2. Switched-mode power supply according to claim 1, characterized in that the converter modules (21, 22) are designed as single-switch, single-ended flux converters with a demagnetization circuit. 3. Switched-mode power supply according to claim 1, characterized in that the converter modules (21, 22) are designed as two-switch common mode flux converters. 4. Switching power supply according to claim 1, characterized in that the converter modules (21, 22) are designed as push-pull flux converters. 5. Switched-mode power supply according to claim 1, characterized in that the charging circuit (41) as a discontinuously operating step-down converter with a choke (63) and two diodes connected to the two poles of the second winding (15) with the same pole and commonly connected to the choke (63) 61, 62) is formed. 6. Switched-mode power supply according to Claim 1, characterized in that the charging circuit (41) is designed as a tip n value-controlled device with a downstream linear regulator. 7. Switched-mode power supply according to Claim 1, characterized in that the charging circuit (41) has a controllable switch (64) with an associated control line. 8. Switching power supply according to claim 1, characterized in that the inductor (63) of the charging circuit (41) with the inductor (73) of an output module (31, 32) is magnetically coupled. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th