DE3337820A1 - Switched-mode power supply - Google Patents

Abstract

A switched-mode power supply having a DC voltage chopper device (4) which is controlled by a pulse-width modulator (12) has a plurality of DC voltage output circuits (15, 16, 17), one (15) of which is connected by means of its DC voltage output (21) to a control input (22) of the pulse-width modulator (12); the further DC voltage output circuits (16, 17) in each case contain controllable inductors (40, 70) in order to control the voltages at their DC voltage outputs (52, 82), which inductors (40, 70) are in each case connected via a control device (57, 87) to the respective DC voltage output (52, 82). In order to be able to connect a plurality of further DC voltage output circuits (16, 17) in parallel, the controllable inductance (40, 70) is an inductor coil with an iron core; the control device (57, 87) contains a controllable switch (63, 94) which, in series with an electrical valve and a resistor (65, 95), forms the respective DC voltage outputs (52, 82) with the controllable inductance (40, 70). Furthermore, each control device (57, 87) contains an appliance (58, 88) for testing the voltage at the respective DC voltage output for exceeding the specified threshold value, the output of the appliance (58, 88) being connected to the control input (64, 93) and forming a control connection (62, 92) of the respective DC voltage output circuit (16, 17). <IMAGE>

Description

Switching power supply

The invention relates to a switched-mode power supply with a transformer, its primary winding with the output of a controllable DC voltage chopper is in connection with its control input at the output of a pulse width modulator is connected, and on its secondary side several DC output circuits each with a DC voltage output, in each DC voltage output circuit one secondary winding of the transformer with the DC voltage output of the respective DC voltage output circuit via a rectifier arrangement and a downstream sieve filter is connected, which is from a storage throttle and a smoothing capacitor is formed, and wherein one of the DC voltage output circuits with its DC voltage output at a control input of the pulse width modulator is connected and the other DC voltage output circuits each one controllable Have inductance in series with the respective secondary winding of the transformer is at the input of the rectifier arrangement and via a control device is connected to the respective DC voltage output.

Such a switching power supply is in the magazine "Der Electronicsiker", Issue 6, 1982 on page 11 ff. The well-known switched-mode power supply (Fig. 1) has a transformer, the primary winding of which is connected to a current transformer is connected to the output of a controllable DC voltage chopper device. The DC voltage chopper device can optionally use its DC voltage input to a battery or via a mains rectifier with a downstream filter connected to an alternating voltage network DC chopper device furthermore has a control input which is connected to the control transformer via a control transformer Output of a pulse width modulator-connected. On the secondary side of the transformer there are several DC output circuits, each with a secondary winding of the transformer via a rectifier arrangement and a downstream output filter with the DC voltage output of the respective DC voltage output circuit in Connection. In the case of a DC voltage output circuit, its DC voltage output is connected to a control input of the pulse width modulator, which supplies the voltage the DC voltage output by controlling the DC voltage chopper regulates to a specified setpoint. For regulating the voltages at the DC voltage outputs of the other DC voltage output circuits, these each contain one of one Controllable inductance formed by a transducer.

The transducer with its working winding is in series with it the respective secondary winding of the transformer at the input of the downstream Rectifier arrangement, while the control winding of the transductor via a control device connected to the DC voltage output of the respective DC voltage output circuit is.

The invention is based on the object of specifying a switched-mode power supply, in which several DC voltage outputs can be switched in parallel.

The solution to this problem is that in the case of the aforementioned Switching power supply for each of the further DC voltage output circuits the controllable Inductance a choke coil with an iron core is that the control device includes a controllable switch that is in series with an electric valve and a resistor parallel to the storage choke of the sieve filter between the DC voltage output and the input of the rectifier arrangement and that the respective Control device furthermore a device for testing the voltage at the respective DC voltage output on exceeding a predetermined threshold value, the output the device is connected to the control input of the controllable switch and forms a control connection of the respective DC voltage output circuit.

An advantage of the switched-mode power supply according to the invention is that for each additional DC voltage output circuit, its DC voltage output is transmitted a controllable switch and an electric valve with the input of the respective Rectifier arrangement is fed back, the controllable inductance only consists of a choke coil with an iron core, which has a high saturation induction having. The voltage at the DC voltage output is reduced to that of the Device for testing the voltage predetermined threshold regulated by during the switch-off time, in which the transformer does not receive any energy from the DC voltage chopper is supplied when the voltage exceeds the specified threshold value at the DC voltage output, part of the demagnetizing current through the storage choke via the controllable switch and the electrical valve of the controllable inductance is fed. The controllable inductance is magnetically pre-saturated in such a way that that in the following switch-on time, in which the transformer from the chopper Energy is supplied, the voltage at the DC voltage output is lower Assumes value.

There is another advantage of the switched-mode power supply according to the invention in that the outputs of the devices to test the voltage on the respective DC voltage output Control connections of the respective DC voltage output circuits form.

The control connections can namely advantageously with one another are connected so that the voltages at the DC voltage outputs of the corresponding DC voltage output circuits are each regulated to the same value and the DC voltage output circuits are parallel at their DC voltage outputs can be connected to each other.

Several of the switched-mode power supplies according to the invention can also be used in the same way connected in parallel to each other at their DC voltage outputs.

In an embodiment of the advantageous because of its simplicity Switching power supply according to the invention, the controllable switch is a transistor whose The collector-emitter path also forms the electrical valve; the device for The voltage test is a series connection of a Zener diode and a series resistor, where the junction of Zener diode and series resistor with the base of the transistor is connected and forms the control connection of the DC voltage output circuit.

In a further advantageous embodiment of the invention Switching power supply contains each DC voltage output circuit a current detection device to monitor the current in the respective DC voltage output circuit for excess a predetermined value; the output of each current detection device is respectively connected to another control input of the pulse width modulator. To this Way, the individual DC voltage output circuits are independent of each other secured against overload due to excessive currents. As soon as in a DC voltage output circuit the current exceeds a predetermined value, activates the respective current detection device the pulse width modulator via its output. This then reduces in the DC voltage chopper the switch-on time in which the transformer Energy is supplied from the chopper on the primary side, so that an overload occurs the switching power supply is prevented. Another benefit is there in the separate current monitoring of the individual DC voltage output circuits, so that each DC voltage output circuit only to the maximum that is intended for it Output power must be designed.

Is a DC voltage output circuit for drawing a high Current to its DC voltage output, it can be advantageous if the associated current detection device contains a current transformer, which with its current path in series with the secondary winding of the transformer and the input the rectifier arrangement and if on the secondary winding of the current transformer a series circuit consisting of a diode and a measuring resistor is connected, wherein the connections of the measuring resistor are the output of the current detection device form. The current path of the current transformer has a particularly low resistance on, so that even with high currents in the DC voltage output circuit in the Power dissipation occurring in the current transformer is very low. Another benefit of the Current converter consists in the fact that it has the respective DC voltage output circuit galvanically isolated from the primary side of the transformer.

In the case of DC voltage output circuits, for a less high current consumption are designed at their DC voltage outputs, a simpler and therefore more cost-effective Structure of the switching power supply achieved in an advantageous manner that the respective Current detection device includes a current detection resistor in series with the output of the sieve filter and the DC voltage output of the respective DC voltage output circuit and that the current detection device furthermore has an optocoupler, the one with its input-side light-emitting diode parallel to the respective current detection resistor is arranged and in which the collector-emitter path of the output-side phototransistor forms the output of the current detection device. Of the Optocoupler brings about a galvanic separation of the primary and secondary side in an advantageous manner of the transformer.

Another advantage of the optocoupler is that as a result of Threshold voltage of the input light emitting diode of the optocoupler of this his The output is only activated when the current flows through the current sensing resistor exceeds a specified value.

To explain the invention, a preferred one is shown in the drawing Embodiment of the switching power supply according to the invention shown.

The switched-mode power supply contains a power rectifier 1, the input side is connected to an AC voltage network and its output 2 to the DC voltage input 3 of a controllable DC voltage chopper device 4 is connected. These has its output 5 on the primary winding 6 of a transformer 7, which is in the illustrated embodiment with the DC voltage chopper forms a single-ended flow converter. The DC voltage chopper device 4 contains a field effect transistor 8, which the primary winding 6 via its drain-source path and a low-resistance source resistor 9 to the DC voltage input 3 of the Facility 4 connects. Instead of the field effect transistor 8 can also be a bipolar Find switching transistor use. The gate connection of the field effect transistor 8 forms a control input 10 of the DC voltage chopper device 4, which with the output 11 of a pulse width modulator 12 is connected. The transformer 7 has a demagnetization winding 13, which is connected to the DC voltage input via a diode 14 3 of the DC voltage chopper device 4 is connected. With the one shown Embodiment has the switched-mode power supply on the secondary side of the transformer 7 three DC voltage output circuits 15, 16 and 17, each connected to a secondary winding 18, 19 and 20 of the transformer 7 are located. In addition, can the switching power supply according to the invention further, not shown here DC output circuits contain. The DC voltage output circuit 15 is with its DC voltage output 21 connected to a control input 22 of the pulse width modulator 12; another Control input 23 of pulse width modulator 12 is connected to output 24 of a current detection device 25 connected. This contains a current transformer 26, which is in series with its current path with the secondary winding 18 of the transformer 7 is located. On the secondary winding of the current transformer 26 is a series circuit of a diode 27 and a measuring resistor 28 connected, the terminals of the measuring resistor 28 connecting the output 24 the current detection device 25 form. The series connection from the secondary winding 18 of the transformer 7 and the current path of the current converter 26 is a rectifier arrangement 29 with their entrance 30-downstream. The rectifier assembly 29 includes a Series connection of a rectifier diode 31 and a freewheeling diode 32, the are connected to one another at their cathode connections. The terminals form of the series connection, the input 30 and the terminals of the freewheeling diode 32 the output 33 of the rectifier arrangement 29. A screen filter 34 is connected to this connected to its input 35. The sieve filter 34 contains a series connection from a storage choke 36 and a smoothing capacitor 37, the terminals the series connection, the input 35 and the terminals of the smoothing capacitor 37 form the output 38 of the sieve filter 34. The output 38 of the sieve filter 34 forms the output 21 of the DC voltage output circuit 15.

The DC voltage output circuit 16 is in series with the secondary winding 19 of the transformer 7 a controllable inductance 40, which consists of a choke coil with an iron core. To the series connection from the secondary winding 19 and the controllable inductance 40 is a rectifier arrangement 41 with its Input 42 connected.

This contains a rectifier diode 43 and a freewheeling diode 44, the same as in the rectifier arrangement 42 of the DC voltage output circuit 15 are arranged. The output 45 of the rectifier arrangement 41 is connected to the input 46 of a screen filter 47 connected, which corresponds to the screen filter 34 of the DC voltage output circuit 15 is formed from a storage choke 48 and a smoothing capacitor 49. The DC voltage output circuit 16 also contains a current detection device 50, which is between the output 51 of the sieve filter 47 and the DC voltage output 52 of the DC voltage output circuit 16 is arranged and with its output 53 is connected to a further control input 54 of the pulse width modulator 12. The current detection device 50 has a current detection resistor 55, which is in series with the output 51 of the sieve filter 47 and the DC voltage output 52 lies. An optocoupler 56 is provided in parallel with the current detection resistor 55 connected to its input-side light-emitting diode, the collector-emitter path of the phototransistor on the output side, the output 53 of the current detection device 50 forms.

The controllable inductance 40 of the DC voltage output circuit 16 is connected to the DC voltage output 52 via a control device 57. The control device 57 contains a device 58 for testing the voltage on the DC voltage output 52 for exceeding a predetermined threshold value. The device 58 consists of a series connection of a Zener diode 59 with a series resistor 60, a capacitor 61 being arranged in parallel with the Zener diode 59 can be. The junction of Zener diode 59 and series resistor 60 forms the Output of device 58 and is used as control terminal 62 of the DC voltage output circuit 16 led out. The control device 57 also contains a controllable switch 63 with its control input 64 at the output of the device 58 is connected. The controllable switch 63 consists of a transistor whose The base connection forms the control input 64 of the switch 63. The collector-emitter path of the transistor forms a valve in series with a resistor 65 and a Diode 66 between the DC voltage output 52 and the input 42 of the rectifier arrangement 41 and is arranged parallel to the storage throttle 48 of the sieve filter 47. the Diode 66 serves to protect the transistor and may be omitted.

The DC voltage output circuit 17 and possibly others in the present one Embodiment of the switching power supply not shown DC output circuits, are constructed in the same way as the DC voltage output circuit 16.

There is also a secondary winding in the DC voltage output circuit 17 20 via a controllable inductance 70 consisting of a choke coil with a Iron core connected to the input 71 of a rectifier arrangement 72.

The rectifier arrangement 72 contains the same as the rectifier arrangements 29 and 41 a rectifier diode 73 and a freewheeling diode 74. At the output 75 the rectifier arrangement 72 has a screen filter 76 connected to its input 77, which contains a storage inductor 78 and a smoothing capacitor 79, and on his Output 80 via a current detection device 81 with the DC voltage output 82 of the DC voltage output circuit 17 is connected. The current detection device Like the current detection device 50, 81 has a current detection resistor 83 and an optocoupler 84 and its output 85 is connected to a further control input 86 of the pulse width modulator 12 is connected. The DC voltage output circuit 17 likewise contains a control device 87 with a device 88 to the Checking the voltage at the DC voltage output 82 for exceeding a predetermined value Threshold. This has a Zener diode 89 with a series resistor 90 and a Capacitor 91, the junction of Zener diode 89 and series resistor 90 form the output of the device 86, which is used as the control terminal 92 of the DC voltage output circuit 17 is brought out. The output of the device 86 is connected to the control input 93 a controllable switch 94 connected; this consists of a transistor that with its collector-emitter path forming an electrical valve in series with a resistor 95 and a diode 96 in parallel with the storage inductor 78 between the DC voltage output 82 and the input 71 of the rectifier arrangement 72 lies.

The voltage from the AC voltage network is used in the network rectifier 1 rectified and sieved. The DC voltage obtained in this way is used in the DC voltage chopper 4 chopped up by the fast switching field effect transistor 8 and placed in the transformer 7 transformed from the primary side to the secondary side. The field effect transistor 8 is controlled by the pulse width modulator 12, the ratio of the Switch-on time in which the transistor 8 is conductive to the switch-off time in which it blocks until it is variable up to 1: 1. During the switch-on time, the energy from the primary side of the transformer 7 to its secondary side to the individual Transmit DC voltage output circuits 15, 16 and 17; during the switch-off time of the Transistor 8 demagnetizes the transformer 7 via the demagnetization winding 13 and the diode 14. On the secondary windings 18, 19 and 20 of the transformer 7, a sequence of square-wave alternating voltage pulses is produced in each case each of which with the help of the rectifier arrangement 29, 41 and 72 a pulse-shaped Direct current is derived, the duration of a current pulse being the switch-on time of the field effect transistor 8 corresponds.

In the case of one DC voltage output circuit 15, the pulse-shaped Direct current in the current detection device 25 is detected by the current transformer 26. In this case, a pulse width modulator 12 is connected to the measuring resistor 28 on its further one -Input 23 controlling voltage drop is generated. As soon as the pulsed direct current exceeds a predetermined value in the current path of the current transformer 26 the DC voltage chopper device 4 by the pulse width modulator 12 in this way controlled that the ratio of the switch-on time to the switch-off time of the field effect transistor 8 decreased.

The pulse-shaped direct current is largely smoothed in the filter element 34, so that at the output 38 of the filter element 34 and thus also at the DC voltage output 21 a DC voltage with low ripple is available. With every current pulse of the pulsed direct current is namely in the storage choke 36 of the filter element 34-magnetic energy stored after the current pulse during the switch-off time of the field effect transistor 8 in the form of a flowing through the freewheeling diode 32 Demagnetizing current is released again. This will also after the current pulse the current flowing through the storage choke 36 is maintained, so that at the DC voltage output 21 a steady direct current can be drawn. The regulation the voltage at the DC voltage output 21 takes place at a predetermined setpoint value through the pulse width modulator 12. As soon as the voltage at the DC voltage output 21 exceeds the specified target value, the pulse width modulator controls the DC voltage chopper device 4 in such a way that the ratio of the switch-on time reduced to the turn-off time of the field effect transistor 8. As a result, transmits the transformer 7 sends less energy to the DC voltage output circuits 15, 16 and 17, so that the voltage at the DC voltage output 21 drops. If against it the voltage at the DC voltage output 21 falls below the specified target value, the DC voltage chopper 4 of the Pulse width modulator 12 controlled in such a way that the ratio of the switch-on time to the switch-off time of the field effect transistor 8 enlarged.

In the further DC voltage output circuit 16 flows in the switch-on time of the field effect transistor 8 from the voltage on the secondary winding 19 with With the help of the rectifier arrangement 41 generated pulsed direct current through the controllable Inductance 40. During a portion of the switch-on time, the controllable Inductance 40 is magnetized until it is saturation induction, thereby forming for the pulsed direct current has a high resistance. After reaching the saturation induction this resistance is only low, so that in the remaining part of the time the pulsed direct current flows unattenuated into the filter element 47. This fulfills the same function as the filter element 34 of the DC voltage output circuit 38: so that at the DC voltage output 52 also a DC voltage with low ripple is available and a steady direct current can be drawn. As soon as the The voltage at the DC voltage output 52 is predetermined by the Zener diode 59 Exceeds the threshold value, this becomes conductive, so that at the series resistor 60 a voltage drop controlling the transistor of the controllable switch 63 arises. The collector-emitter path of the transistor acts as an electrical valve, that only in the turn-off time of the field effect transistor 8 when the storage choke 48 is demagnetized, is conductive.

Part of that supplied by the storage choke 48 then flows Degaussing current through the controllable switch 63, the resistor 65 and the diode 66 into the controllable inductance 40. In this way, the controllable Inductance 40 premagnetized in such a way that in the following turn-on time of the field effect transistor 8 a particularly large amount of time is required to adjust the controllable inductance 40 by the current pulse of the pulse-shaped direct current mes up to to magnetize their saturation induction. Only after reaching the saturation induction the controllable inductance 40 forms a low resistance for the pulse-shaped Direct current, so that only a little in the remaining time portion of the switch-on time Energy flows into the screen filter 47 and the voltage at the DC voltage output 52 goes down.

In the further DC voltage circuit 17, the voltage on the DC output 82 in the same manner as for the DC output circuit 16 regulated. To enable parallel operation of the two other DC output circuits 16 and 17, their control connections 62 and 92 are connected to one another, so that the voltages at the two DC voltage outputs 52 and 82 to that of the Zener diode 59 or 89 specified with the lower Zener voltage in each case Threshold to be regulated.

1 Figure 5 claims

Claims (5)

Claims chalt power supply with a transformer, the primary Wick Mchalt power supply Sung in connection with the output of a controllable DC voltage chopper device which is connected with its control input to the output of a pulse width modulator is, and on its secondary side several DC output circuits each with a DC voltage output, wherein in each DC voltage output circuit one secondary winding of the transformer with the DC voltage output of the respective DC voltage output circuit via a rectifier arrangement and a downstream sieve filter is connected, which is from a storage throttle and a smoothing capacitor is formed, and wherein one of the DC voltage output circuits with its DC voltage output at a control input of the pulse width modulator is connected and the other DC voltage output circuits each one controllable Have inductance in series with the respective secondary winding of the transformer is at the input of the rectifier arrangement and via a control device is connected to the respective DC voltage output, d a d u r c h g e k It is noted that in each of the further DC voltage output circuits (16, 17) the controllable inductance (40 or 70) a choke coil with an iron core is that the control device (57 or 87) has a controllable switch (63 or 94) in series with an electric valve and a resistor (65 resp. 95) parallel to the storage choke (48 or 78) between the DC voltage output (52 or 82) and the input (42 or 71) of the rectifier arrangement (41 or 72) and that the respective control device (57 or 87) continues to have a device (58 or 88) to check the voltage at the respective DC voltage output (52 or 82) for exceeding a predetermined threshold value, the Output of the Device (58 or 88) with the control input (64 or 93) of the controllable switch (63 or 94) is connected and a control connection (62 or 92) of the respective DC voltage output circuit (16 or 17). 2. Switching power supply according to claim 1, d a du r c h g e -k e n n z e i c h n e t that the controllable switch (z. B 63) is a transistor whose collector-emitter path also forms the electrical valve and that the device (e.g. 57) a series connection of a Zener diode to test the voltage (59) and a series resistor (60), the junction of Zener diode (59) and series resistor (60) is connected to the base of the transistor and the Control connection (62) of the DC voltage output circuit (-16) forms. 3. Switching power supply according to claim 1 or 2, d a d u r c h g e k e n It is clear that each DC output circuit (15, 16, 17) has a current detection device (25, 50, 81) for monitoring the current in the respective DC voltage output circuit (15, 16, 17) for exceeding a predetermined value and that the output (24, 53, 85) of each current detection device (25, 50, 81) to a further one Control input (23, 54, 86) of the pulse width modulator (12) is connected. 4. Switching power supply according to claim 3, d a d u r c h g e -k e n n z e i c h n e t that at least one current detection device (25) has a current transformer (26) contains the current path in series with the secondary winding (18) of the Transformer (7) and the input (30) of the rectifier arrangement (29) is and that on the secondary winding of the current transformer (26) a series circuit of one Diode (27) and a measuring resistor (28) is connected, the connections of the measuring resistor (28) form the output (24) of the current detection device (25). 5. Switching power supply according to claim 3 or 4, d a d u r c h g e k e n n z e i c h n e t that at least one current detection device (z. B. 50) a Contains current detection resistor (55) in series with the output (51) of the sieve filter (47) and the DC voltage output (52) of the respective DC voltage output circuit (16) and that the current detection device (50) also has an optocoupler (56), which with its input-side light-emitting diode parallel to the respective Current detection resistor (55) is arranged and in which the collector-emitter path of the phototransistor on the output side, the output (53) of the current detection device (50) forms.