DE1613979C3 - - Google Patents

Description

negative pole marked 18. Other DC voltage sources can of course also be used. Via an input line 10 into which an on-off switch 20 and a fuse 41 are switched are, the positive pole of the battery 40 with the anode 12 is α of a first four-layer triode 12 connected. The cathode 12 c of the first four-layer triode is with the first winding end 24 one Switching throttle 23 connected. Between the first winding end and a central tap 26 extends the first partial winding 25 of the switching throttle, while the second partial winding 27 of the center tap 26 extends towards the second winding end 28. With the second winding end 28 is the anode 30 a of a second four-layer triode

30 connected. The cathode 30 c of this triode is connected to the anode of a diode 56, the cathode of which is connected to the negative pole 18 of the battery 40 via a return line. Between the input line 10 and the return line 10 a are two series-connected diodes 21 and 22 in the reverse direction on the battery 40. The connection point of the two diodes is in the manner described below electrically connected to the center tap 26 of the switching throttle 23.

Parallel to the center tap 26 of the switching throttle and the two four-layer triodes 12 and 30 a commutation capacitor 32 or 33 is connected. The connection point of the two capacitors is connected to the center tap via a line

31 connected. The connection point of the two commutation capacitors is connected to the return line 10 a via a series circuit of a choke 14 a, a capacitor 14 b and a resistor 66, which smooths the pulsating DC voltage between the line 31 and the return line 10 α, so that a load 16, a relatively constant voltage can be supplied via an output line 15 connected to the connection point between choke 14 a and capacitor 14 b.

The control electrodes 12 g and 30 g are connected via control lines 58 and 61 and the cathodes 12 c and 30c are connected to a control unit 57 via control lines 60 and 62, respectively, the lines 60 and 58 or 61 and 62 are combined in pairs to form lines 34 and 35, respectively. With help of a On the control unit 57 formed adjusting knob 57 a can on the lines 34 and 35 control signals are given to the switching times of the controllable four-layer triodes 12 and 30 steer.

Between the input line 10 and the return line 10 a is a series circuit of one Resistor 42 and a zener diode 43; Furthermore, an input filter capacitor is between the lines 10 and 10 α 44 laid.

The connection point of the two diodes 21 and 22 is through the primary winding 48 of a regenerative transformer 47 is connected to the center tap 26 of the switching throttle 23. The secondary winding 50 of the regenerative transformer 47 is on the one hand with the connection point of the two Diodes 21 and 22 and on the other hand connected to the connection point of two further diodes 45 and 46, which are in series between the input line 10 and the return line 10 a and with respect to ■ the poles of the battery are polarized in the same way as the first two diodes 21 and 22. Parallel a filter capacitor 51 is connected to the secondary winding Return of energy during the commutation interval when the load supplies energy that is greater than the energy delivered by the battery to the load.

The first four-layer triode 12 is assigned a junction trap circuit, which consists of one with the Input line 10 connected capacitor 52 and a resistor 53, which between the capacitor and the cathode 12 c of the first four-layer triode. Consisting of a similar circle of a capacitor 54 and a resistor 55 is between the anode 30 α of the four-layer triode 30 and the return line 10 α switched.

The connection point of the two diodes 21 and

22 and the connection point of the resistor 42 and the Zener diode 43 are connected to the input of the control unit via control lines 71 and 72, which are combined to form a line 73. The voltage present across the resistor 66 is tapped via lines 67 and 68 and is likewise fed to the input of the control unit via a line 70. Likewise, the voltage between the output line 15 and the load return line 15 α, ie the voltage across the capacitor 14 b, is tapped via lines 63 and 64, which are fed back as a common line 65 to the input side of the control unit 57.

During operation of the DC / DC converter, a control pulse is first sent via line 34 given to the control electrode of the four-layer triode 12 in order to switch it through. When connected Four-layer triode 12, a current flows from the positive terminal 17 via the switch 20, the four-layer triode 12, the partial winding 25 of the switching inductor, the conductor 31, the load 16, the Return line 10 α to the negative pole of the battery 40. While this current is flowing, the commutation capacitor 33, which is connected in parallel to the second four-layer triode 30, via the line 31 and the diode 56 polarized in the charging current direction is charged.

Depending on the position of the adjusting knob 57 α of the control unit 57, a later Time a control pulse via line 35 or control lines 61, 62 to the second four-layer triode 30 placed, whereby this is applied in a known manner and the first four-layer triode 12 is switched off. The capacitor 33 is discharged via the second partial winding 27 of the switching inductor 23 and the second four-layer triode 30. As a result of the transformer effect of the switching inductor

23 the voltage required for switching off is thus applied to the four-layer triode 12, whereby this is switched off and remains switched off for the required time interval, so that accordingly, only the four-layer triode 30 remains in the switched-on state. An unloading over the Load 16 cannot take place because diode 56 is polarized in the opposite direction of the discharge current.

A multivibrator circuit can be used for the control unit, which has two stable states has, with the multivibrator at the beginning of the reference time always by a pulse from a Reference oscillator is output, is set in the most state and after a time interval has elapsed

valls, the length of which can be determined by setting the adjusting knob 57 α , can be set in the second state. For example, the setting knob can change the effective value of a resistor that is connected in series with a capacitor in a charging circuit and is used to regulate the time interval that the capacitor needs to charge to a certain voltage, which in turn regulates the operation of the multivibrator.

On the basis of FIG. 2 A to 5 B, the circuit sequence will now be explained again in more detail. First, the setting knob 57 a is set so that the DC / DC converter delivers an output voltage to the load 16 that is approximately 3/8 or 0.375 of the input or supply voltage E that is present between the poles 17 and 18. A first control pulse is then emitted via line 34, which switches on the four-layer triode 12 at time zero. According to the illustration in FIG. 2A, the triode 12 remains switched on for about 3/8 of the reference time interval between O and T. At time J ₁ , a control pulse is emitted via line 35, which switches triode 30 on and triode 12 off. No energy is therefore delivered from the DC voltage source to the load between times ij and T.

Because of the series connection consisting of choke 14 α and capacitor 14 b , an essentially constant output voltage is delivered to load 16 between times O and T, as shown in FIG. 2B is shown. It is assumed in this representation 2B that the output voltage starts from the value 0, but then remains at approximately 3/8 of the input voltage E. Even after the triode 12 has been switched off at time t _t , a current path via diode 22, primary winding 48, choke 14 a, load 16 and return line 10 α is maintained, so that the average value is maintained. Choke 14 a and capacitor 14 b must therefore be dimensioned so that a current is maintained in the circuit just described between times t _x and T. It can be seen that the load current flowing through the load 16 along the current path just described after the triode 12 has been switched off does not flow through the triode 30 either.

If the setting of the control unit 57 is changed by actuating the setting button 57 a in order to achieve an output voltage corresponding to approximately 3/16 or 0.187 of the input voltage £, the switch-on time of the triode 12 according to FIG. 3 A reduced; This means that the average output voltage delivered is in the range shown in FIG. 3 B reduced in the manner shown. The F i g. 4 A and 4 B show the mode of operation when an output voltage in the amount of approximately 3/4 or 0.75 of the supply voltage E is emitted, while FIGS. 5 A and 5 B show the operating mode when the output voltage should only be 50%> the supply voltage E.

The output of the control pulses via the lines 34 and 35 is controlled by the input side via the lines 65, 70 and 73 supplied control signals controlled. The voltage tapped at resistor 66 represents a measure of the magnitude of the load current. For this reason, resistor 66 only has a value of a few ohms in order to avoid an additional load on the DC / DC converter. The voltage tapped off by means of lines 63 and 64 is transmitted via line 65 as a further signal fed to the load of the control unit.

The third signal supplied via line 73 is a measure of the battery voltage. If the The level of the supply voltage drops, this can be automatically compensated for by the control unit 57 be that the turn-on time of the triode 12 in each complete time period by a corresponding Amount is extended that the output voltage is essentially constant and at the level of the through the setting knob 57 a holds the set value. Should the voltage on the load increase, so will caused by the signal supplied via the line 65 that the turn-on time of the triode 12 within of each complete time period is reduced and thus in a corresponding manner that of the DC / DC converter output energy is lowered, so that in conjunction with the higher on the voltage applied to the load, the desired constant output voltage between the output line 15 and the associated return line 15 α is maintained. When at the load one Short-circuit occurs, the large current flowing through resistor 66 gives a signal that the Control unit 57 causes the triode 12 to be turned off until the short circuit in the burden is lifted. In this way, excessive discharge of the battery 40 is avoided.

During operation of the arrangement, the commutation capacitor assigned to the second four-layer triode 30 can be charged to a voltage which is greater than the supply voltage lying between the input line 10 and the return line 10 α. This increase in voltage is caused by the voltage surge occurring in the switch-over inductor 23 during the commutation process, which has the same polarity as the supply voltage.

For this purpose 2 sheets of drawings "

Claims (2)

Claim: DC voltage converter for obtaining a DC voltage that can be controlled or regulated in terms of its size from an existing constant DC voltage, in which a first four-layer triode, which is used exclusively to conduct the load current, with its anode connected to the positive Pole of the DC voltage source and with its cathode to one end of a switching choke is connected and a second four-layer triode, which is exclusively responsible for the deletion of the first Four-layer triode is used, with its anode on the other end of the switching inductor and with its Cathode connected to a current path leading to the negative pole of the DC voltage source is where the load is between the center tap of the switching throttle and the negative one Pole of the DC voltage source is connected, in which further parallel to the center tap the switching inductor and the two four-layer triodes each have a commutation capacitor is switched and in which two diodes in series in the reverse direction at the DC voltage source and are connected with their common connection point to the center tap of the switching throttle, thereby characterized in that the cathode of the second four-layer triode (30) and the terminal of the parallel capacitor (33) via a diode (56) to the negative pole (18) are connected to the DC voltage source (40). The invention relates to a DC / DC converter for obtaining a size Controllable or adjustable DC voltage from an existing constant DC voltage, in which a first four-layer triode, which is used exclusively to carry the load current, with its anode on the positive one Pole of the DC voltage source and connected with its cathode to one end of a switching choke and a second four-layer triode, which is exclusively responsible for the erasure of the first four-layer triode serves, with its anode to the other end of the switching throttle and with its cathode a current path leading to the negative pole of the DC voltage source is connected, in which the Load between the center tap of the switching throttle and the negative pole of the DC voltage source is connected, in which further parallel to the center tap of the switching throttle and the two Four-layer triodes each have a commutation capacitor connected and two in series Diodes are in the reverse direction on the DC voltage source and with their common connection point are connected to the center tap of the switching throttle. Such a circuit is known. When the first four-layer triode is switched on and If current is carried and the second four-layer triode is ignited, that of the second four-layer triode is discharged assigned commutation capacitor that can be charged to the existing DC voltage via one of the partial windings of the switching reactor and via the load. The one flowing over the load Current is lost for the commutation process. The commutation current becomes the one by the value of the existing DC voltage and the other by the division ratio determined between load and partial winding (U.S. Patent 3,250,978). It is the object of the invention to provide a DC voltage converter of the above type, in which an increased current flows through the switching reactor during commutation. ίο The object is achieved according to the invention by that the cathode of the second four-layer triode and the connection of the parallel capacitor are connected to the negative pole of the DC voltage source via a diode. The capacitor lying parallel to the second four-layer triode is set to a higher DC voltage charged than the intended DC voltage, since the occurring during the commutation process in the switching reactor Voltage surge added to the specified DC voltage. As long as this tension is higher than the voltage on the load, the diode prevents this higher voltage from being reduced. Additionally prevented The diode also means that when the second four-layer triode is switched through at the beginning of the commutation process part of the commutation current can flow through the load; rather, the whole flows Discharge current determined by the higher voltage via the switching choke. It is an inverter with two connected in series Four-layer triodes per phase and with external charging known, in which the anode of the first of the two four-layer triodes and the connection of the commutation capacitor lying parallel to the triode via a first Diode is connected to the positive pole of the input rectifier bridge of the inverter and the cathode of the first triode is electrically connected to the anode of a second four layer triode is whose cathode and the connection point of the commutation capacitor lying parallel to the second four-layer triode are connected to the negative pole of the rectifier via a second diode. The two connection points of Four-layer triode electrode, diode and commutation capacitor are, however, with the outputs connected to a rectifier serving for external charging, that of one phase of the input AC voltage is fed. The diodes prevent the external charging voltage of the input rectifier bridge the capacitors charged to the external charging voltage are impressed or are impressed discharge towards the bridge if the external charge voltage is greater than the output voltage the bridge, which output voltage should vary over a wide range (British Patent specification 1047 916). The invention will now be described in more detail using an exemplary embodiment. Of the Figures shows F i g. 1 shows a block diagram of the DC / DC converter according to the invention and FIG F i g. 2 A to 5 B the graphical representation of time-voltage functions to explain the mode of operation the invention. The DC voltage source used in the FIG. 1 a battery 40 used, whose positive pole is 17 and whose ne-