DE3335398A1 - DC voltage converter - Google Patents

Abstract

A DC voltage converter having a continuous input current with a continuous output current, with a power circuit breaker (T) which can be switched on periodically and storage inductors (L1/L2) which act in the input circuit and output circuit and maintain the current flow in the connected load resistor (R) with the aid of the magnetic energy stored in them, via a coupling capacitor (Ck), during the phase when the power circuit breaker (T) is switching on and off. <IMAGE>

Description

DC voltage converter

The invention relates to a DC voltage converter in the generic term of claim 1 described Art.

Modern DC voltage converters have electronic circuit breakers, the input circuit periodically with the output circuit or between input Connect the transformer provided and the output circuit for galvanic isolation, so that a DC output voltage is created, the level of which depends largely on the pulse duty factor of the circuit breaker, i.e. the time ratio of the switch-on phase to the switch-off phase is determined.

DC voltage converters work with relatively high switching frequencies, space requirements and weight of the magnetic components involved, such as storage chokes and isolating transformer to keep it as small as possible. The high switching frequencies can, on the other hand, be a source of interfering noises which are filtered through suitable screening means must be suppressed in the input and / or output circuit. This is especially true when the converter in the input and / or output circuit is not continuous instead it absorbs or emits current in pulses. Hence there is an endeavor To develop DC-DC converters, both in the input circuit and in the output circuit always carry electricity. Such a converter is described, for example, in DE-OS 28 42 262 known. This well-known converter achieves the goal of continuous input and output current in that a converter with continuous input current electricity, namely a so-called boost converter, combined will with such the continuous output current supplies.

The invention is based on the object of a DC voltage converter to create a constant both in the input and output circuit Direct current leads.

This task is performed by a DC / DC converter with the characteristics of claim 1 solved.

Advantageous refinements and developments of the invention are Subject of the subclaims, to which hereby expressly to shorten the description is referred.

The invention is explained in more detail below with reference to the drawings: Fig. 1 shows a first embodiment of a DC voltage converter according to of the invention, Fig. 2 shows a further DC voltage converter according to the invention with an isolating transformer for galvanic separation of the input and output circuit, Fig. 3 shows a further embodiment of a DC voltage converter according to of the invention, Fig. 4 shows a DC voltage converter according to the invention a transformer for voltage translation and / or for quasi-galvanic isolation of input and output circuit.

The DC voltage converter shown in Fig. 1 has a with a supply voltage source Ue connectable input circuit and one with a load resistor R connectable output circuit. There is no galvanic isolation between input and output circle. There is a in the series branch between the input and output circuit Circuit breaker T inserted from an external clock source can be switched on and off. The duty cycle, i.e. the ratio between the switch-on and switch-off time of the circuit breaker T is preferably in accordance with the load resistance R and / or the input voltage Ue adjustable to the output voltage designated with Ua keep constant.

In the lying between the input and the circuit breaker T. A throttle L1 is inserted into the section of the series branch. Another choke L2, which can be inductively coupled to the choke L1 is in series with a rectifier D connected to a shunt branch of the output circuit. A coupling capacitor Ck connects the winding connection of the choke L1 facing away from the input with the connection point between the choke L2 and the mentioned rectifier D.

The circuit shown in Fig. 1 operates as follows: If the input voltage Ue is switched on, the coupling capacitor Ck overcharges the windings of the two chokes L1 and L2. As soon as the circuit breaker T reaches its conductive state, on the one hand, current flows from the supply source Via the choke L1 and the circuit breaker T into the load resistor R. On the other hand A current flows in the same direction via the choke L2, the coupling capacitor Ck and the circuit breaker T also into the load resistor R. If the circuit breaker T blocks, supplies the magnetic energy stored in the throttle L2 in the usual way Way through the rectifier D current in the load resistor R. At the same time supplies the magnetic energy stored in the choke L1 via the coupling capacitor Ck and the rectifier D also current to the load resistor R.

So it flows constantly, i.e. during the switch-on phase and during the switch-off phase of the circuit breaker T, current both in the entrance as well as in the starting circle.

In the circuit shown, the two chokes are L1 and L2 magnetically coupled. The prerequisite for this is that the with the coupling capacitor Ck connected winding connections given the same induction voltage and phase position are. This is the case when the windings of both chokes are on a common Core are applied and have essentially the same number of turns.

The embodiment of the invention shown in FIG. 2 differs differs from the circuit according to FIG. 1 in that the coupling capacitor Ck is not directly connected to the output circuit but with another inductor winding L3 is connected in series, which is magnetically coupled to the chokes L1 and L2 is. A prerequisite for this magnetic coupling is again that the with the Circuit breaker T or the rectifier D connected winding ends, respectively the same induction voltage and phase position prevail, i.e. all inductor windings when arranged on a common core have approximately the same number of turns.

The circuit shown in Fig. 2 operates in the following way: When the supply voltage Ue is switched on, the coupling capacitor Ck charges on it on. When the circuit breaker T becomes conductive, flows through the choke L1 and the Circuit breaker T current in the output circuit. At the same time flows out of the condenser Ck through the inductor winding L3 and the circuit breaker T also current into the Output circle. When the circuit breaker T blocks, it builds up in the choke L2 stored magnetic energy via the rectifier D into the output circuit from, i.e. the choke L2 continues to supply current to the load resistor R.

At the same time, however, flows in the leakage inductance of L1 and L3 stored magnetic energy in the coupling capacitor Ck, so that this is reloaded.

In the embodiment shown in Fig. 3 is a transformer Tr intended for voltage adjustment. One can put this circuit together think of a flyback converter and a forward converter, whose input circuits are in Series and their output circuits are connected in parallel. The coupled with each other Chokes L1 and L2 form the transformer of the flyback converter. To the lowest possible To achieve current ripple in the output circuit, the transformation ratio between the windings of the chokes L1 and L2 the transmission ratio of the transformer Tr adapted. If this transmission ratio from the primary to the secondary side with n, the quotient L2 / L1 of the choke inductances should be approximately the Correspond to value n2. The coupling capacitor Ck is - also in adaptation to the Transmission ratio n - with a tapping of the throttle L1 and / or the throttle L2 connected. Since the input and output circuit through the coupling capacitor Ck directly are connected to each other, there is no real galvanic separation of the two circuits given. If the input and output circuit have different reference potentials should, the corresponding terminals in the circuit shown are designated by "-", via a further coupling capacitor designated by Ck1 be connected to each other.

It should also be mentioned that the formed by the inductances L1 and L2 Flyback converter transformer in the interest of good magnetic storage capacity should have a comparatively large air gap, while the transformer Tr des Flow converter part - as usual - a small air gap and thus small Should have leakage inductances.

Fig. 4 shows an embodiment of the invention in which a real galvanic separation between the input and output circuit is provided. To this Purpose, another inductance L2 'is provided, which is connected in series with the Rectifier D arranged in the shunt arm of the output circuit and with the choke L1 and / or L2 is magnetically coupled.

The mechanism of operation of the circuits shown in Figs corresponds - as far as the embodiment according to the invention is concerned - essentially the circuit of FIG. 1, so that a detailed description of the same is unnecessary. A major advantage of the circuit according to FIG. 4 is that by suitable choice the transmission ratio of both the flyback converter transformer and the forward converter transformer almost any voltage and current adjustment made in the secondary circuit can be.

It should also be mentioned that the transformer Tr to generate a Multiple output voltages that are identical or different from one another and are independent of one another may have a corresponding plurality of secondary windings. In this case is in each of the output circuits an inductor winding corresponding to inductor L2 ' to be provided, all of which are magnetically coupled to the throttle L1 and / or L2.

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Claims (7)

Claims 0 DC voltage converter it one to a DC supply voltage source connectable input circuit and at least one connectable to a load resistor Output circuit - with one arranged in a series branch of the input circuit Choke, - with a power switch for periodic connection of the input circuit to the DC supply voltage source, - as well as one arranged in the output circuit Storage choke to maintain the flow of current in the load resistor during the switch-off phase of the circuit breaker, with the relevant current flow over a rectifier runs during the switch-on phase of the circuit breaker is in the blocking state, characterized in that - the storage choke (L2) Via a coupling capacitor (Ck) with the choke arranged in the input circuit (L1) is connected in such a way that the coupling capacitor (Ck) is connected to the DC supply voltage source is chargeable, - that the storage choke (L2) when the circuit breaker becomes conductive (T) absorbs energy from the charged coupling capacitor (Ck), so that the magnetic energy stored in it during the switch-on phase of the circuit breaker (T) an additional current flow via the coupling capacitor (Ck) and the power switch (T) in the output circuit - and that during the switch-off phase of the circuit breaker (T) the index of the first-mentioned choke (L1) stored magnetic energy additional current flow via the coupling capacitor (Ck) and the rectifier (D) causes in the output circuit. 2. DC voltage converter according to claim 1, d a d u r c h g e k e n It is not indicated that the first-mentioned throttle (L1) faces away from the input Winding end or with a tap via the coupling capacitor (Ck) with a Winding end or a tap of the storage choke (L2) is connected, and that the connection point between the coupling capacitor (Ck) and the storage choke (L2) the mentioned rectifier (D) with the live connection (+) of the output circuit connected is. 3. DC voltage converter according to claim 1 or 2, d a -d a d u r c h g e k e n n n z e i c h n e t that the arranged in the longitudinal branch of the input circuit The choke (L1) and the storage choke (L2) are magnetically coupled. 4. DC voltage converter according to claim 1, d a d u r c h g e k e n n z e i c h n e t that a third throttle (L3) is provided, which both with the first-mentioned choke (L1) as well as with the storage choke (L2) magnetically is coupled that this third choke (L3) in series with the coupling capacitor (Ck) a winding end facing away from the input or a tap of the first choke (L1) connected shunt arm of the input circuit, and that the Storage choke (L2) in series with the rectifier (D) in a parallel branch of the output circuit is arranged (Fig. 4). 5. DC voltage converter according to one of claims 1 to 4, with a Transformer for galvanic isolation and / or voltage adjustment of input and output circuit, d a -d u r c h e k e n n n z i c h n e t that the turns ratio the chokes or the tapped winding parts to the transmission ratio of the Transformer is adapted. 6. DC voltage converter according to one of claims 1 to 3 or according to claim 5, with a transformer for galvanic separation of input and output circuit, d a -d u r c h e k e n n n z e i c h n e t that the storage choke two galvanically separated and magnetically coupled windings (L2, L2 '), one of which (L2) in series with the coupling capacitor (Ck) in the cross arm of the input circuit and the other (L2 ') in series with the rectifier (D) is arranged in the cross arm of the output circuit. 7. DC voltage converter according to claim 6 with an isolating transformer with several output windings to form a corresponding plurality of galvanic output circuits that are independent of each other e t that one corresponding to the number of output windings of the isolation transformer Number of storage chokes is provided and that all of these storage chokes with which is arranged in series with the coupling capacitor in a shunt arm of the input circuit second choke are magnetically coupled.