DE2901761A1 - Push=pull power converter circuit - has transformer bridge and alternately closed switching bridge reducing voltage loading - Google Patents

Abstract

A push-pull power converter circuit contains a transformer (Tr) whose secondary coil drives a rectifier, filter, and load. Each primary coil (W1) half is connected in a side branch of a bridge circuit with one of two alternately closed switches (S1, S2) driven by a pulse width regulator (PBR). The diagonal bridge arm contains a direct voltage source (Uo) and choke (U) connected in series between the switch junction and primary coil centre tapping. Its blocking voltage loading and switching transistor power loss are essentially reduced compared to conventional circuits. It produces a continuous output current and requires relatively small additional component cost. An additional bridge circuit is formed with its side branches each contg. a primary coil half and one of two further alternately closed switches (S1', S2') driven by (PBR). The diagonal arm contains a further choke (L2) magnetically coupled to the first choke (L1).

Description

Push-pull flow converter

The invention relates to a push-pull forward converter with potential separating Transformer, on the secondary side of which a rectifier arrangement, for example a voltage multiplier, can be connected, in a bridge circuit, whose Series branches (side branches) push-pull switches and their cross branches (Diagonal branch) one in series with a voltage source, for example direct voltage, switched choke included.

Such a push-pull flow converter is for example by DE-PS 25 36 371 became known. This circuit works with discontinuous Input or output current and thus requires a large amount of sieve means. Switching with current jumps is, however, subject to very high power losses.

In particular, if the circuit is working with underload just switched off when the current has reached its maximum amplitude. Even with nominal load, every switchover from the mean current amplitude to Switched to zero. This releases very high reverse voltages too great loads of the mostly semiconductors, especially transistors Switch lead.

With the article "The Venable converter" by R. Hayner et.al.

in PESC 1976, RECORD (IEEE) a push-pull forward converter is described, in which the primary winding of the transformer has a center tap and another two symmetrical taps and those connected in series with the DC voltage Throttle also contain a tap. With the help of four switches, one of which only switches one at a time, one end of the primary winding is now alternating to one end of the choke or the tap of the primary winding adjacent to this end connected to the throttle tap. With the same tap ratio both at Choke as well as the two primary winding halves can be a continuous Output current can be achieved. However, the input current is not continuous, and with every second switchover, namely when the throttle tap off and the end of the choke is switched on, it is switched exactly at the current maximum. the The maximum reverse voltage at the switches is twice that of this circuit Output voltage, where the output voltage with Ul = Uo. (1 - T1. (1-n)) n T always is greater than the input voltage Uo, where T is the duty cycle and n is the number of turns ratio of tap to total winding. For small values of n, for example the case when the fluctuation range of the input voltage Uo is relatively large, the maximum reverse voltage can assume very high values.

In the invention, the object was therefore set to provide a push-pull forward converter with significantly lower reverse voltage load and significantly lower power loss specify the switching transistors that deliver a continuous output current, the additional cost of additional components should be relatively low.

This problem is solved by what is specified in the claims Middle.

The solution according to the invention is now described on the basis of of the figures. Fig. 1 shows a first embodiment of the invention, at that of the potential-separating transformer that translates with the number of turns ratio ü Tr, on whose secondary winding a rectifier arrangement with subsequent sieving and load is connected, with its primary winding W1 two first series branches a bridge circuit and four switches S1, S1 ', S2, S2' two further pairs of series branches form this bridge circuit. Between the center tap of the primary winding W1 and the two common points of switches S1, S2; S1 ', S2' are cross-branches a first choke L1 in series with a DC voltage source Uo or a second one Choke L2 that is magnetically coupled to the first choke L1 and the same Has inductance value. With the switching sequence S1, S1 ', S2, S2', S1 ... becomes alternately one increasing at the closing times of the switches S1, 52 and at the closing times of the switches S1 ', S2' a falling continuous Current achieved. The ratio T1 / T of the closing time T1 of the switches S1 and S2 to Cycle time T, the total closing time of S1 and S1 'or S2 and S2' is from a the output voltage regulating pulse width regulator PBR is set. The output voltage U1 is thus equal to the input voltage Uo multiplied by T1 / T. As a maximum The reverse voltage at the switches is at most twice the output voltage U1 plus the input voltage Uo or, in other words, that multiplied by (1 + 2T1 / T) Input voltage Uo.

The advantage of this push-pull forward converter according to the invention lies So in the fact that with continuous output current a smaller reverse voltage and a smaller power loss in the switches with at most the same or even Less effort compared to the Venable Converter, assuming that the both chokes L1 and L2 are wound on the same core, and in that the two taps on the primary winding side of the transformer Tr omit to be achieved.

In addition, it is achieved by the solution according to the invention that the Switch of the series branch pairs whose common point with a connection point of the a throttle containing shunt arm is connected, at the same current amplitudes have to switch, while the Venable Converter has different current amplitudes are to be switched. In a further embodiment of the invention, the effort reduced even further by using only one throttle L, which is used only once and on the other hand via the DC voltage source Uo either to one or to the other the other end of the primary winding W1 of the transformer Tr is switched. This circuit, in which the same switching sequence is provided as in Fig. 1, in Fig. 4 shown.

2 and 3 are further embodiments of the invention shown. Fig. 2 shows a push-pull forward converter in a bridge circuit, two bridges are superimposed so that the primary winding W1 of the transformer Tr in the common first shunt branch, two push-pull switches S3, S4 in the two common series branches, the two switches S1, S2 the series branches and a first choke L1 connected in series with a DC voltage source Uo the cross branch of a first bridge and the other switches working in push-pull S1 ', S2' in the series branches and a second throttle L2 in the cross branch a second bridge circuit. The switching order of the switches in the non-common series branches of the bridge circuits is exactly the same as after Fig. 1 or

Fig. 14, namely S1, S1 ', S2, S2', S1 ... The switches S3, S4 in the common series branches are switched in cycles, i.e. switch S3 is during the closing time of S1 resp.

S1 'and the switch S4 is during the closing time of S2 and S2' closed. This embodiment of the invention also has small Savings voltages and also small power losses in the switches with continuous Output current. It is particularly important that the polarity reversal of the primary winding W1 of the transformer Tr is switched in the current minimum.

Finally, FIG. 3 gives the exemplary embodiment of the invention Fig. 2, but only with a single choke L again, the switches as bipolar Switching transistors are executed. To avoid the inverse operation of the two Switching transistors S1 ', S2' in the two non-common series branches of the second Bridge circuit, i.e. to avoid a negative reverse voltage on these switching transistors, a diode D becomes the inductor L in in the shunt arm of this second bridge circuit Connected in series. This exemplary embodiment according to the invention also has the same features Invention idea with the advantages of the small reverse voltage, the small loss performance at continuous Output current and with continuous Choke current, which means that the switching transistors do not have a different current load than that caused by the minimum or maximum current amplitude of this inductor current subject. The advantage of the single choke L over the circuit, for example according to Fig. 2, is obvious by saving winding space for the second throttle will.

Claims (10)

Push-pull flow converter Claims push-pull flow converter with transformer, on whose secondary winding a rectifier arrangement with a following Sieving and load is connected, in gap circuit, whereby the series branches (bridge side branches) two alternately closing switches or the primary winding of the transformer and the cross branch (diagonal branch) between the common point of the switches and the center tap of the primary winding in series with a (direct) voltage source included switched choke, characterized by a further bridge circuit, those of the two containing the primary winding (W1) of the transformer (Tr) Series branches of the first bridge circuit, from two further series branches with two further alternately asleep switches (S1 ', S2') and a shunt branch with a second throttle (L2) between the common point of these switches (S1 ', S2 ') and the center tap of the primary winding (tal) of the transformer (Tr) (Fig. 1). 2. Push-pull forward converter with transformer on its secondary winding a rectifier arrangement with subsequent filtering and load is connected, in bridge circuit, with four switches in the series branches (side branches), the alternately, opposite in pairs, close the primary winding of the transformer in the first cross branch (diagonal branch) between the common points of these longitudinal branches and a choke connected in series with a (DC) voltage source in the second Cross branch (diagonal branch) between the other two common points of the longitudinal branches are, characterized by a further bridge circuit that consists of the first bridge circuit by replacing two longitudinal branches with two more from two more alternately closing switches (S1 ', S2') formed series branches and by another at their common point and at the common point of the opposite longitudinal branches (S3, S4) connected second throttle (L2) is created as a replacing second shunt branch (Fig. 2). 3. Push-pull forward converter with transformer on its secondary winding a rectifier arrangement with subsequent filtering and load is connected, in bridge circuit, with four switches in the series branches (side branches), the alternately, opposite in pairs, close the primary winding of the transformer in the first cross branch (diagonal branch) between the common points of these longitudinal branches and one in series with a (DC) voltage source switched Throttle in the second cross branch (diagonal branch) between the other two common ones Points of the series branches, characterized by another bridge circuit, from the first bridge circuit by replacing two series branches (S1, S2) two formed from two further alternately closing switches (S1 ', S2') Longitudinal branches and through the at their common point or at the common point of the opposite series branches (S3, S4), connected throttle (L1) as a substitute second branch is created (Fig. 3). Push-pull forward converter with transformer on its secondary winding a rectifier arrangement with subsequent filtering and load is connected, in a bridge circuit, the series branches (side branches) two alternately closing Switch or the primary winding of the transformer and the shunt branch (diagonal branch) between the common point of the switches and the center tap of the primary winding contain a choke connected in series to a (DC) voltage source, characterized by another bridge circuit, which consists of the two primary winding (W1) of the transformer (Tr) containing series branches of the first bridge circuit, from two further longitudinal branches with two further switches closing alternately (S1 ', S2') and a shunt arm that connects the choke (L) but not the (DC) voltage source contains, between the common points of the other longitudinal branches (S1 ', S2') and the center tap of the primary winding (W1) exists (Fig. 4). 5. push-pull flow converter according to one of claims 1 to 14, characterized characterized in that alternately the first, then the further and thereafter then again the first bridge circuit and so on to form a closed one Circuit can be switched in such a way that the first change does not change direction, with the second change, however, there is a change in direction of the transformer flow he follows. 6. Push-pull flow converter according to one of the preceding claims with the exception of claim 3 or 14, characterized in that the second throttle (L2) is magnetically coupled to the first choke (L1) and has the same inductance has (Fig. 1, 2). 7. push-pull flow converter according to one of the preceding claims, characterized in that the current direction in the series branches during the switching changes preserved. 8. push-pull flow andler according to one of the preceding claims, characterized in that the switch (S1, 1 ', ... S4) semiconductors can be used, for example bipolar or field effect transistors (Flg. 3). 9. push-pull flow converter according to claim 8, characterized in that that the further branch also contains a series-connected diode (D) (Fig. 3). 10. push-pull flow converter according to one of the preceding claims, characterized in that the switches S1, S1 ', ... 34) by one the output voltage regulating pulse width regulator (PBR) can be operated (Fig. 1).