DE4008652C2 - Power supply unit with DC-DC converter - Google Patents

Description

The invention relates to a power supply according to the preamble of claim (DE 35 09 853 A1).

The operating DC voltages required by electronic consumers are often used by Switching power supplies generated. With switched-mode power supplies, the mains voltage is first rectified and sieved. The direct voltage thus obtained is switched on by means of a contactless switch chopped up. The switch is turned on and off at a high frequency operating frequency. The voltage generated by the chopping is translated with a transformer that the galvanic isolation of the electronic consumer from the network. The operating DC voltage can be regulated, with the switch working as an actuator. The Be drive frequency and / or the duty cycle of the switch is used to regulate the operation DC voltage changed.

In switched-mode power supplies, the DC-DC converters are switched on gating circuit directly to the AC network or via an input circuit the DC network connected. In general, the rectifiers are charging capacitors downstream. Due to the charging capacitors, the direct current direct current Transformer in the event of brief mains voltage drops with sufficient for operation Energy are supplied. If the power supply is switched on at the maximum voltage, arise from the charging of the charging capacitor high current surges, for the z. B. the Components of the rectifier circuit must be designed.  

Large current surges also occur with short-circuit or overcurrent loads on the direct current DC converter. The dimensioning of the components for interference suppression of the switch power supply also depends on the maximum possible inrush currents and the Ripple of operating currents. At the same time, these components influence the height of the Inrush currents.

A medium-frequency converter is known from German Offenlegungsschrift DE 24 45 093 A1 known to deliver a stabilized DC voltage. For electrical isolation between A transformer is provided for the input and output voltage, the primary circuit of which is load can be influenced depending on switching transistors controllable by the output voltage. At In this embodiment there is a first connection of the primary winding via a transistor at a first pole of a DC voltage source and a second connection of the primary winding tion via a second transistor at a second pole of the DC voltage source. Because teren are parallel to the primary winding of the transformer diodes for switching stream.

Measures to set a lower rate of increase in primary currents are not provided.

From DE 35 09 853 A1 is a circuit arrangement for DC voltage DC voltage conversion known. The circuit contains a choke on the input side DC voltage source is connected, and on the output side at least one choke with is connected to a consumer. So that the DC voltage source with a relative uniform current is loaded, it is provided that the input-side choke on the one hand a capacitor is connected via a diode and on the other hand a switch is connected, which is still connected to the DC voltage source and by a switching regulator can be actuated periodically. The output choke is with a capacitor and one Free-wheeling diode connected. In a further embodiment it is provided that the DC-DC converter has two output circuits, one Transformer has a primary winding and two secondary windings.

The invention has for its object a power supply of the type described above further develop that works after the chopper operation, but to avoid the  Expenses for radio interference suppression means has a low rate of increase in the primary currents.

The object is achieved by the characterizing features of the patent claim solved.

With this arrangement, an input current of low ripple or low on arises rate of climb. The effort for radio interference suppression can therefore be reduced. The choke reduces the rate of increase of the primary current. Hereby savings can be achieved in the design of the radio interference suppressor. The throttle limits the slew rate of the primary currents so that the transistors and the Elements of the rectifier circuit not for those far above the nominal operating currents Currents must be designed because the current limitation, not shown, overcurrents quickly detected.

The invention is described below with reference to the embodiment shown in a drawing examples described in more detail, from which further details, features and advantages surrender.

Show it:

Fig. 1 is a circuit diagram of a first power supply,

Fig. 2 is a circuit diagram of part of a second power supply.

A power supply has connections 1 , 2 for the AC network. A rectifier circuit 3 is connected to the connections 1 , 2 , which is preferably a bridge rectifier which has outputs 4 and 11 .

A charging capacitor 23 is connected in parallel with the outputs 4 , 11 . The series connection of a contactless switch 24 , the primary winding 25 of a transformer 26 , a choke 27 and a second contactless switch 28 is arranged in parallel with the charging capacitor 23 or the outputs 4 , 11 . The two contactless switches 24 , 28 have the same structure and are, for. B. designed as bipolar transistors. A diode 29 , which is also referred to as a freewheeling diode, is arranged between the output 11 and the common connection point of the primary winding 25 and the choke 27 .

Another diode 30 , which is also referred to as a freewheeling diode, is arranged between the output 4 and the common connection point of the choke 27 and the switch 28 .

A diode 32 , to which an output 33 is connected, is connected to the secondary winding 31 . The other output 34 is connected to one end of the secondary winding 31 . Chokes are not present in the secondary circuit of the transformer 26, at least up to the outputs 33 , 34 , at which an output DC voltage is available. The outputs 33 , 34 are connected to a control circuit 35 for the switches 24 , 28 . The DC output voltage of the secondary circuit is regulated by means of the control circuit 35 . For this purpose, a controller, not shown, is used, as is known per se. The two switches 24 , 28 are controlled both conductive and non-conductive. The transformer 26 has only a low inductance. In addition to the secondary winding 31 , there may be further secondary windings for additional voltages that are not regulated. A capacitor 38 is connected in parallel with the outputs 33 , 34 .

If the two switches 24 , 28 are controlled to conduct, a current flows from the rectifier circuit 3 and the charging capacitor 23 via the primary winding 25 and the inductor 27 . This current induces voltages in the secondary winding 31 and in further secondary windings, not shown. If the switches 24 , 28 are controlled in a non-conducting manner, then the current of the inductor 27 flows via the freewheeling diodes 29 and 30 and charges the charging capacitor 23 . The switches 24 , 28 are switched at a high-frequency operating frequency. The capacitance of the capacitor 23 is small, so that only low charging currents occur. The choke 27 limits the current flowing through the transformer 26 . Since there are no chokes in the secondary circuits, good tracking of the unregulated DC output voltages is guaranteed. The arrangement shown in FIG. 1 takes currents with low effective values from the AC network. The radio interference suppressor, e.g. B. the filter 22 , can therefore be designed for the damping of relatively small currents.

Fig. 2 shows part of a power supply. With regard to the connections 1 , 2 of the filter 22 , the rectifier circuit 3 , and the charging capacitor 23 , there is agreement between the power supply unit according to FIG. 2 and the power supply unit shown in FIG. 1.

Therefore, the connections 1 , 2 , the filter 22 and the rectifier circuit 3 have not been shown in FIG. 2.

Correspondence between the arrangements shown in Fig. 1 and Fig. 2 is also in relation to the series connection of the switch 24 , the primary winding 25 of the transformer 26 , the inductor 28 and the secondary circuit of the transformer 26 with the secondary winding 31 , the diode 32nd , the capacitor 38 and the outputs 33 , 34 . However, the order between the primary winding 25 and the choke 27 is reversed in the series connection. Identical elements are provided with the same reference numbers in FIGS . 1-2. The arrangement according to FIG. 2 differs from the arrangement shown in FIG. 1 in that the two freewheeling diodes are connected. There are also two diodes 39 , 40 , which are referred to as free-wheeling diodes. One freewheeling diode 39 is connected with the cathode to the output 4 and with the anode to the common junction of the choke 27 and the primary winding 25 . The freewheeling diode 40 is connected with the anode to the output 11 and with the cathode to the common connection point of the switch 24 and the choke 27 . The mode of operation of the arrangement according to FIG. 2 corresponds to that of FIG. 1.

Claims (1)

1. power supply unit with a DC-DC converter, which contains a transformer, the primary winding of which is connected to a connection in series with a transistor to a pole of a DC voltage source and is connected at the other connection to the other pole of the DC voltage source via a choke, wherein a rectifier and a smoothing capacitor is connected to the secondary winding of the transformer, and wherein the DC voltage applied to the smoothing capacitor is applied to a control circuit which feeds the transistor with a high-frequency control voltage, characterized in that between the inductor ( 27 ) and the pole ( 11 ) the DC voltage source, a further transistor ( 28 ) acted on by the same control voltage as the first transistor ( 24 ) is arranged in series with the choke ( 27 ), that a capacitor, ( 23 ) is connected in parallel to the poles of the DC voltage source, that to the series circuit d he choke ( 27 ) and the further transistor ( 28 ) a first freewheeling diode ( 29 ) and to the series connection of the primary winding ( 25 ) of the first transistor ( 24 ) and the choke ( 27 ) a second freewheeling diode ( 30 ) are connected in parallel.