DE3410684A1 - Electronically controlled inductive voltage converter - Google Patents

Abstract

In the case of this electronically controlled inductive voltage converter, which is used for voltage multiplication in power supply arrangements, an inductor (1) which is present anyway in the further circuit arrangement is used in a multiple manner. For example, the mains transformer (7) is operated in an electrically duplicated manner using the time-sharing method, as a transformer and as a converter inductance. <IMAGE>

Description

Electronically controlled inductive voltage converter.

The invention relates to an electronically controlled inductive voltage converter, in particular for voltage multiplication in energy supply devices, for Supply of electrical or electronic circuit arrangements, or corresponding driven electrical / electronic consumer, with at least one there inductance provided in a circuit, in particular in the form of a transformer, or a choke, or a relay, or a motor, to name a few.

The known such voltage converters are with one or more Inductors are provided in a variety of applications not just one Quite a significant economic factor when considering the entire effort an electrical or electronic energy supply device in detail, as well as together with electrical or electronic circuit arrangement fed thereby or a comparable electrical / electronic consumer, but that too, especially if such a voltage converter is arranged on a circuit board is, h often have a considerable weight and a relatively large space requirement require. In addition, it may be necessary with the known voltage converters that the inductive arrangement there must be shielded to avoid any interference in neighboring circuit arrangements.

The invention is based on the object of a voltage converter to create the aforementioned type for circuit arrangements of the aforementioned type, which does not suffer from the disadvantages of the known voltage converters, but the circuitry in the overall circuit of an electrical to be supplied or electronic circuit arrangement or an electrical or electronic Consumers should be integrated, with the previously required inductance for the voltage converter is to be replaced, i.e. to be saved.

The invention is characterized in claim 1 and in subclaims further arrangements are claimed.

This is advantageous with such an integration of a voltage converter in an overall electrical or electronic circuit arrangement to be energetically fed is not only the intended use of one in the circuit arrangement to be fed existing transducer-unspecific induction, i.e. the intended dual function such an induction, but also the weight and space savings that can be achieved thereby, as well as the economic efficiency of the overall circuit arrangement that can be achieved as a result.

The invention is shown in some application examples in the drawing and is explained in more detail below. 1 shows a circuit a voltage multiplier using the power supply transformer, FIG. 2 shows a circuit according to FIG. 1 with an inductance between the double function and buffer electronics connected to the voltage multiplier, FIG. 3 shows a circuit arrangement with a relay in the power supply device, its inductance in a Dual function with the voltage converter or voltage multiplier works, Fig. 4 shows a circuit arrangement of a power supply device with a latching relay in the fed electronic circuit arrangement, its inductance with the Voltage multiplier works in a double function.

According to the circuit of FIG. 1, a buffered battery 4 is via the Power pack 5 charged. The transistor 6 is blocked in this case.

In the event of a power failure, the transformer 7 would be inoperative. Of the Transistor 6 would then be conductive. The voltage multiplier circuit or the voltage converter 8 would then be over; the transistor 6 from the battery 4 fed. Of the Voltage converter 8 works with the inductance 1 of the transformer 7 as a so-called Oscillating transformer in the manner of a single-ended flyback converter. Of course is also the operation of the voltage converter 8 as a so-called single-ended forward converter or provided as a push-pull chopper, with an inductance 1 in a double function.

In the present circuit according to FIG. 1, the permanent connection between the transformer 7, i.e. the inductance 1 and the voltage converter 8 only effective after a power failure, especially since the voltage converter 8 is connected Network is switched off by transistor 6 as buffer 3.

According to the circuit of FIG. 2, the voltage converter B is accordingly a voltage multiplier, through the buffer 3 at mains be operated completely from the Double-function inductance 1 in the transformer 7 separately. Working in buffer 3 for this purpose a two-phase semiconductor circuit.

According to the circuit of FIG. 3, the inductance 1 is used there Auxiliary relay 9 in an electronic one fed by the power supply device Circuit arrangement 10 as a double-function inductor 1 for a voltage converter 8 or voltage multiplier. The relay 9 can only be used there when the mains voltage is applied be energized. If the network fails, the transistor 6 becomes conductive, the inductance 1 of relay 9 de-energized, i.e. voltage converter 8 is working.

In the circuit according to FIG. 4, an accumulator 4 is charged via the power supply unit S. The transistor 6 is then blocked. However, the relay 9 also works when there is no Network. It is fed by the voltage converter 8. This relay 9 is only pulsed there controlled. During this time, the charge of the capacitor 11 takes over the buffering the power supply, especially since the voltage converter 8 does not do so in the intermediate pulse time is working. By the way the voltage converter 8 works, in particular by its Current consumption, the relay 9 is not energized. The voltage converter 8 works extremely well low energy.

Instead of the inductance 1 of the relay 9 in FIG. 4, there is an inductance 1 of a motor, especially a stepping motor, stepped.

This stepper motor is there every second for, for example, 60 msec.

controlled. In the rest of the time, the motor works from the voltage converter 8 fed. Here, too, the voltage converter works extremely low-energy, so that in During the pauses between steps, the motor is not excited by the voltage converter operation.

In this application, it is conceivable that both the relay 9 as well as a stepper motor connected there constantly parallel to the voltage converter 8 are connected and working, especially since the voltage converter has a relatively high operating frequency possesses and thus problem-free parallel to a relay 9 or a comparable Engine can work.

Claims (11)

Claims 1. Electronically controlled, inductive voltage converter, in particular for voltage multiplication in energy supply arrangements, for supply of electrical or electronic circuit arrangements, or operated accordingly electrical / electronic consumer, with at least one there in a circuit provided inductance in particular in the form of a transformer, or a Choke, or a relay or a motor, characterized in that an inductance (1) from a powered electrical / electronic circuit arrangement or a powered electrical / electronic loads for the voltage converter (2) is effective in a double electromagnetic or electrodynamic function. 2. Voltage converter according to claim 1, characterized in that the, Inductance (1) operated in a double function via a buffer (3) at least non-reactive with regard to an electrical / electronic functional circuit is decoupled. 3. Voltage converter according to claim 2, characterized in that the Buffer (3) is provided with an electrical / electronic filter. 4. Voltage converter according to claim 2 and 3, characterized in that that the buffer (3) is provided with an electronic noise blanker is. 5. Voltage converter according to claim 1 and 2, characterized in that that the inductance (1) is operated in a time-sharing process is. 6. Voltage converter according to claim 1 and 2, characterized in that that the inductance operated at two different frequencies at the same time will. 7. Voltage converter according to claim 1 and 2, characterized in that that the inductance with a static voltage and a superimposed frequency is operated. 8. Voltage converter according to claim 1 and 2, characterized in that that the voltage converter only works when the inductance is in its electrical Function is only available to the voltage converter. 9. Voltage converter according to claim 1, 2 and 8, characterized in that that the voltage converter can only work automatically when the inductance in its electrical function is only available to the voltage converter. 10. Voltage converter according to claim 1, characterized in that the existing inductance carries an additional winding for the voltage converter. 11. Voltage converter according to claim 1 and 2, characterized in that that the inductance by the electrical function with the voltage converter is not is brought into satiation.