DE4212864A1 - Voltage converter with source and consumer circuit separation - has rechargeable battery in energy store, parallel connected to output terminals - Google Patents

Abstract

The voltage converter has galvanically separated the primary source circuit from the secondary consumer circuit. The converter has several switching arrangements, each with a switch and a storage. The switch first connects the storage for charging of the primary circuit and then for discharging to the secondary circuit. The discharge periods of the individual storages are arranged in a time sequence. According to the type of circuit contg. the primary and secondary terminals, either a d.c. voltage converter or an inverter is formed. If a rectifier circuit is used, the circuits provide an inverter or a rectifier. USE/ADVANTAGE - For miniature transformer replacement, with facility for supplying consumer appliance for longer period, on primary voltage failure.

Description

The invention relates to a voltage converter with the The preamble of claim 1 features listed.

In AC circuits, the often required galvanic separation between the source and the consumer Circuit mainly through an electrical trans formator solved. Even a rectifier is usually a transformer connected upstream of the DC circuit galvanically isolated from the mains. For the electrical isolation of two DC circuits (e.g. with a DC voltage converter) it is known to chop the DC currents to transform chopped stream and then right back to prepare. Galvanic isolation is less common Motor-generator combination causes. Optoelectric Coupling elements and relays are only included for this purpose very small services (information transfer) in question.

A transformer works almost maintenance-free and with good efficiency, but it is relatively large, heavy and expensive, and cannot be miniaturized. So it was Try to close the galvanic isolation without the help a power transformer to cope with.

Various solutions to this problem belong to the state of the art Technology. In SU 2 90 374 there is a DC-DC converter described, in which the connections of a capacitive and / or inductive energy storage using two Switch groups alternately to the supply network and on the consumer can be switched so that the consumer is fed from the energy storage and not a direct one Has contact with the supply network, i.e. galvanically works separately.  

The circuits that work out also work on this principle DE-A-24 35 392 or DE-A-20 52 382 are known. Here is the basic circuit using capacitive voltage dividers extended as well as by connecting a rectifier circuit to a rectifier with the galvanic Separation expanded. From EP 03 86 261 it is known that the Curve shape of the input voltage at the output better again is given when several basic circuits in parallel be switched. A rectifier circuit with two basic circuits connected in parallel work with double path rectification. Capacitive voltage dividers and Voltage multipliers are also in DE-A-20 62 258 described, also a use of the reason circuit as an AC converter, the switching frequency of the contacts large compared to the frequency of the Input voltage is.

All of these circuits have capacitive energy stores and inductive storage elements. This allows this Circuits when the source voltage fails the consumer supply only for a very short time, for the emergency power sources they are not suitable.

The problem of the AC converter was only for small achievements solved since one for the memory cards sensors that are reversed and with a high switching frequency charge and discharge, no electrolytic capacitors or Can use accumulators.

The problem of an inverter with galvanic isolation was not addressed in the above writings. So his solution is not an obvious consequence of that known circuits (such as the parallel switching of two Inverters without galvanic isolation in GB 20 98 414 A proves).

The object of the present invention is accordingly on the basis of a generic voltage converter to further educate the consumer in the event of failure of the Can supply primary voltage with energy longer than that known circuits and / or as an inverter galvanic isolation of input circuit and output circuit can be operated.

Both the AC converter and the change richter problem is solved by the present invention solved that a first basic circuit for the positive and a second for the negative half waves of the input and / or output voltage is provided. This eliminates the restriction regarding the switching frequency of the Contacts, and the memory elements are not reversed still fully discharged so that you have electrolytic capacitors and / or can use batteries as energy storage.

Further developments and advantageous refinements of the Voltage converter according to the invention are the subject of Subclaims.

The following are exemplary embodiments of the invention Reference to the drawings explained in more detail. Show it:

FIG. 1a is a circuit diagram of a voltage converter according to a first embodiment of the invention,

Fig. 1b is a circuit diagram of the output part of a second embodiment of the invention, and

Fig. 2 is a block diagram of part of another embodiment of the invention.

A voltage converter 12 according to the invention contains at least one energy transmission circuit 1 '. The energy transmission circuit contains a memory for electrical energy 3 ', for. B. a reactance, such as an inductance or a capacitor, in particular an electrolytic capacitor or preferably a rechargeable battery (accumulator); further contains the energy transmission circuit 1 'a suitable switch arrangement 2 ', which is controlled by a control device, not shown, and the energy storage 3 'alternately either only with the primary 4 ', 5 ', or only with the secondary circuit 6 ', 7 'connects . As a result, the electrical energy is transferred from the primary circuit into the storage arrangement 3 'during a period of time t ₁ and then, during a period of time t ₂ , the stored electrical energy is offered to the secondary circuit. A charge-discharge process is created, which is repeated with a repetition frequency f ₁ .

Two or more such energy transmission circuits 1 ', 1 '',. . . can be connected on the primary side and / or secondary side either in parallel (type I, Fig. 1a) or so interconnected that the positive output terminal 6 'is connected to the negative output terminal 7 ''of the next energy transmission circuit and a secondary or output connection 10 of the voltage converter forms (type II, Fig. 1b).

In order to implement a DC voltage converter, a DC voltage is applied to the primary connections of the voltage converter, and the input connections and the output connections of all energy transmission circuits according to Art I are connected. An almost uninterruptible DC voltage is then available at the secondary connections of the voltage converter. A charging capacitor on secondary connections 10 , 11 can further reduce the ripple of this voltage. If connections 10 , 11 are connected in parallel with an accumulator 14 , an emergency power source is obtained.

With the output circuit according to Art II, this circuit results an inverter with a single or multi-phase secondary AC voltage if you have energy for each phase transmission circuit provides.

In order to feed the voltage converter from an AC voltage source, it is advisable to connect it with at least one rectifier circuit or to assign at least one rectifier circuit 13 to each energy transmission circuit (e.g. 1 ', 1 '') ( FIG. 2). If you then switch the inputs and outputs of the individual energy transmission circuits according to type I ( Fig. 1a), you get a potential-free DC voltage with the help of a charging capacitor or an accumulator 14 on the secondary connections 10 and 11 .

Switching the outputs of two energy transmission Circuits according to Art II are due to the secondary connections an alternating voltage, and the Circuit represents an AC converter.

An AC voltage converter is also created when the input connections, with an upstream rectifier 13 , Fig. 2, and the output connections of the energy transmission circuits according to Type II are interconnected.

With one from a multi-phase AC voltage source fed AC converters will enter each phase Assigned voltage transformers.

With all AC converters, it is useful that Switching over each individual switch arrangement with the Synchronize frequency of the primary AC voltage. By the synchronous rectification can some rectifiers circuits become superfluous.  

If the primary and secondary voltages are to have the same shape, the switching frequency of the switch arrangements (e.g. 2 ′, 2 ′ ′) should be chosen accordingly and the charging and discharging constants of the memory arrangements ( 3 ′, 3 ′ ′) accordingly small, so that the form of the primary voltage sampled is obtained as an envelope of the secondary pulses. A continuous secondary voltage can be synthesized therefrom with a downstream integration element and / or a low-pass filter.

Preferably come as switches in the switch arrangements controllable switches in question, such as relays, transistors, IGBT, thyristors, triacs.

A free choice of the time period t ₁ and / or t ₂ enables the secondary voltage to be set and / or controlled. If this control is carried out depending on the change in secondary voltage, the secondary voltage can thereby be kept almost constant.

The upstream of a rectifier circuit acc. Fig. 2 before each of the two power transmission circuits 1 ', 1 '', it is equivalent to the terminal 8 via a two-pole rectifier (not shown) (eg a diode) with the terminal 4 ' and directly with the terminal 5 '' connect and connect the terminal 9 directly to the terminal 5 'and via a second two-pole rectifier (not shown), which is polarized like the aforementioned rectifier, to the terminal 4 ''.

Claims (13)

1.Voltage converter with electrical isolation of the primary (source) circuit from the secondary (consumer) circuit, with at least two primary connections ( 8 , 9 ), at least two secondary connections ( 10 , 11 ) and at least one energy transmission circuit (e.g. 1 '), which has two input connections ( 4 ', 5 '), at least one switch arrangement ( 2 '), at least one electrical energy storage arrangement ( 3 ') and two output connections ( 6 ', 7 '), the switch arrangement ( 2 ') Connects the storage arrangement ( 3 ') to the input connections ( 4 ', 5 ') during a first period (t ₁ ) in order to enable the storage of electrical energy from the primary circuit of the voltage converter, then the storage arrangement ( 3 ') from the input connections ( 4 ', 5 ') and connects them for a second period (t ₂ ) with the secondary connections ( 6 ', 7 ') to discharge the spoke ranordnung ( 3 ') in the secondary circuit of the voltage converter ( 10 , 11 ), which ensures that, in this successively repeating loading and unloading game, the storage arrangement during each charging process only with the primary connections and during each unloading process only the secondary connections are connected and the discharge periods are staggered in time in the case of a plurality of power transmission circuits operated in parallel, characterized in that

• a) at least one rechargeable battery (accumulator) ( 14 ) is provided in the energy storage arrangement ( 3 ') and / or the output connections ( 6 ', 7 ') are connected in parallel, and / or
• b) the voltage converter contains at least two energy transmission circuits ( 1 ', 1 '', Fig. 1a) and the input connections ( 4 ', 4 '' and 5 ', 5 '') of the same polarity of all energy transmission circuits are interconnected and the input connections ( 8 , 9 ) of the voltage converter (type I, Fig. 1a), and / or the output connections ( 6 ', 6 ''and 7 ', 7 '') of the same polarity of all energy transmission circuits are interconnected and the output connections ( 10 , 11 ) of the voltage converter (type I, Fig. 1a), and / or each of the input connection (z. B. 4 'or 5 ', Fig. 2) predetermined polarity of an energy transmission circuit with the input connection different polarity of the next energy Carrier circuit is connected, and each forms an input connection of the voltage converter, and / or in each case the output connection of a predetermined polarity of an energy transmission circuit with the Output connection of different polarity ( 6 'with 7 ''or 7 ' with 6 '') of the next energy transmission circuit is connected and each forms an output connection ( 10 , 11 ) of the voltage converter (type II, Fig. 1b), so that each type mentioned the connection of the input connections can be used with any type of connection of the output connections mentioned in a voltage converter.

2. Voltage converter according to claim 1, characterized in that a direct voltage can be applied to the primary connections ( 8 , 9 ) and both the input connections ( 4 ', 5 ', 4 '', 5 '') and the output connections ( 6 ', 7 ', 6 '', 7 '') at least two energy transmission circuits are switched so that the memory arrangements ( 3 ', 3 '') deliver voltages of the same polarity to the secondary connections ( 10 , 11 ) ( Fig. 1a). 3. Voltage converter according to claim 1 for converting DC voltage into AC voltage, characterized in that a DC voltage can be applied to the primary connections ( 8 , 9 ) and that the input connections ( 4 ', 5 ', 4 '', 5 '') and the Output connections ( 6 ', 7 ', 6 '', 7 '') are switched so that the memory arrangements ( 3 ', 3 '') alternately supply voltages of opposite polarity to the secondary connections ( 10 , 11 ) ( Fig. 1b). 4. Voltage converter according to claim 3, characterized in that one voltage for each phase of the output voltage converter is present. 5. Voltage converter according to claim 1 and 2 for converting AC voltage to DC voltage, characterized in that the primary connections ( 8 , 9 ) is connected upstream of at least one rectifier arrangement, and / or that each energy transmission circuit ( 1 ', 1 '') at least one The rectifier circuit is assigned ( 13 , Fig. 2). 6. Voltage converter according to claim 3 or 4, characterized in that the primary connections ( 8 , 9 ) is connected upstream of at least one rectifier arrangement, and / or that each power transmission circuit is assigned at least one rectifier circuit. 7. Voltage converter according to claim 1, which works as an AC voltage converter, characterized in that an input (z. B. 4 ', 4 '') of each energy transmission circuit, a two-pole rectifier is connected in series and both the input connections of the energy transmission circuits ( 4 ', 5 ', 4 '', 5 '') and their output connections ( 6 ', 7 ', 6 '', 7 '') are interconnected so that the memory arrangements ( 3 ', 3 '') alternating voltages opposite Deliver polarities to the secondary connections. 8. Voltage converter according to claim 5, 6 or 7, characterized characterized in that the power transmission circuits work synchronously with the primary AC voltage. 9. Voltage converter according to claim 1, characterized in that from the shape of the primary voltage sufficiently accurate buttons, a correspondingly high switching frequency for the Switch arrangements of the voltage converter and accordingly small loading and unloading time for its storage arrangements are selected so that the envelope of the secondary voltage Shape of the primary voltage. 10. Voltage converter according to one of claims 1 to 9, characterized in that the switch arrangements control bare switches, such as relays, transistors, thyristors, Triacs, IGBT included. 11. Voltage converter according to one of claims 1 to 10, characterized in that the memory arrays each at least one rechargeable battery and / or at least contain an electrical reactance. 12. Voltage converter according to one of claims 1 to 11, characterized in that the period (t ₁ ) during which the respective memory arrangement ( 3 ', 3 '') with the primary connections ( 8 , 9 ) is connected, and / or the period (t ₂ ) during which the respective memory arrangement ( 3 ', 3 '') is connected to the secondary connections ( 10 , 11 ) is variable, as a result of which the secondary voltage can be set and / or controlled. 13. Voltage converter according to claim 1 to 12, characterized in that the period (t ₁ ) during which the respective memory arrangement ( 3 ', 3 '') is connected to the primary connections ( 8 , 9 ), and / or the period (t ₂ ) during which the respective memory arrangement ( 3 ', 3 '') is connected to the secondary connections ( 10 , 11 ), is controlled as a function of the secondary voltage so that the secondary voltage remains essentially constant.