EP2107861A1 - Switching device for reducing voltage - Google Patents

Abstract

The arrangement (201) has a transformer (206) i.e. autotransformer, arranged between a voltage connection point (202) and a supply connection point (204). A transformer voltage connection (210) is arranged on the voltage connection point. A fixed or movable griping part (214) produces a gripping voltage on the supply connection point, where the arrangement is designed such that a circuit element (212) is closed to reduce the gripping voltage at a consumer load (216) during operation of the arrangement while connecting the load between the griping part and the supply connection point. An independent claim is also included for a method for controlling a consumer load i.e. illumination unit.

Description

The present invention relates to a circuit arrangement for uninterrupted voltage lowering of an electrical AC voltage to a consumer, in particular a lighting means. Furthermore, the present invention relates to a method for controlling at least one electrical load, in particular a lighting means.

It is well known that some lighting devices that are powered by alternating current require a higher voltage when switched on than in the subsequent continuous operation. It is thus desirable or even necessary to turn on such lighting means with a higher voltage and then to reduce the voltage after a short starting time dependent on the respective lighting means.

To change an AC voltage, the use of a transformer is known. The removable voltage from a transformer depends on the magnitude of an input voltage and the turns ratio. In case of Using a so-called autotransformer using only one coil, the removable voltage depends on the position of a tap on the coil. To lower the output voltage for driving a lighting means, the position of the tap and thus the resulting voltage can be changed. However, such a change of the tap during operation is complicated and in particular, this short-term interruptions can occur. Such interruptions may, however, lead to a re-switch-off in some lighting means, and the lower voltage applied after the cut-out would not be enough to turn it on.

In another variant, a fixed Transformatorabgriff is used, which is switched to after the startup time after switching on the lighting means. But even such a switch pulls a brief interruption with it, which can also have the re-switching of the lighting means result. To remedy this problem, an attempt was made to use very fast switches or relays to switch over, which switch over so fast that avoiding switching off the illuminant is avoided. However, such very fast switches are - if they solve the problem at all - extremely expensive and susceptible to wear.

The object of the present invention was therefore to remedy the above-mentioned problems as much as possible and in particular to provide a solution in which a voltage reduction for a drive voltage for an electrical load, in particular a lighting means, is achieved in a simple manner as interruption-free as possible.

According to the invention, a circuit arrangement according to claim 1 is proposed.

A circuit arrangement according to the invention for the uninterrupted voltage drop of an electrical alternating voltage to a load, in particular a lighting means, thus has at least one voltage connection point and a reference connection point for providing a electrical connection AC voltage in between. As a result, in particular an energy saving at the consumer should be achieved. Thus, in connection with the switched-on state, an AC connection voltage can be present between these two points. For example, the reference connection point may be connected to a neutral conductor of a connection network and correspondingly have a grounding potential. The voltage connection point may then have a first electrical phase with respect to the reference terminal point and thus the ground potential in the example mentioned. The electrical phase could correspond, for example, to an electrical phase of a supply network. Likewise, the supply voltage of the network could first be transformed, in particular transformed down in its voltage level. In one embodiment, the reference terminal carries the electrical phase and the voltage terminal is connected to a ground potential. In both cases, instead of the earth potential, basically any other potential can be used, or the electrical alternating voltage between the two points is not related to a fixed voltage potential, ie, this results solely as a relative voltage between the two points.

Between the voltage connection point and the reference terminal point, a transformer, in particular an autotransformer is arranged. By using a transformer, a voltage transformation can be achieved in a known simple manner. An autotransformer is particularly preferred for reducing costs and also for reducing weight and / or overall volume. The transformer is connected to a transformer voltage terminal at the voltage connection point and is connected via a first switching means to a transformer reference terminal at the reference terminal point. In addition, a first tap for providing a first tap voltage is provided on the transformer, wherein the tap voltage refers to the reference terminal point. The first tap may be fixed or variable, so that the voltage ratio of the tap voltage to the AC connection voltage is either fixed or variable accordingly.

The transformer reference terminal is thus not connected directly but via a first switching means to the reference terminal point. The circuit arrangement is prepared to close the first switching means, thereby reducing the tap voltage at the load during operation of the circuit arrangement and thus during operation of the connected load, in particular a connected lighting means, when connected between the first tap and the reference connection point.

For driving a connected consumer, the circuit arrangement is thus initially put into operation such that an electrical AC connection voltage is established between the voltage connection point and the reference connection point. For this purpose, the circuit arrangement preferably comprises a switch-on means for switching on the circuit arrangement. Here, the first switching means is open. Characterized in that the first switching means is opened, the transformer is connected in this state only with its transformer voltage connection to the voltage connection point and its tap on the consumer. The voltage transformation effect of the transformer does not set in this case and the connection AC voltage thus drops substantially to the addressed consumer. The consumer is therefore connected in this state to a relatively high voltage.

If now the first switching means closed and thus the transformer reference terminal connected to the reference terminal, the transformer unfolds its effect as a voltage divider and the voltage at the connected load, so the voltage between the first tap and the transformer reference terminal decreases. The reduction is - depending on the dimensions of the transformer - essentially determined by the geometry and structure of the transformer. Accordingly, the voltage at the load is reduced.

By switching the first switching means thus an interruption of the power supply of the consumer can be avoided. This is by it reasons that the switching of the first switching means has no influence on the current path, which extends from the voltage connection point via the transformer reference terminal, through part of the transformer, via the tap and the connected consumer, to the reference terminal point. The current from the voltage terminal to the reference terminal thus does not undergo interruption by the operation of the first switching means. On the shift quality or switching speed of the first switching means is not important.

Preferably, a second switching means is connected between the voltage connection point and the first tap to establish an electrical connection therebetween in a closed state. By means of this second switching means, a part of the transformer can thus be bypassed and the load connected to the tap can be electrically connected directly to the voltage connection point. In this case, the entire electrical connection AC voltage drops across the load. Thus, for example, voltage drops in the supply network, the maximum available voltage can be ensured at the consumer. It should preferably be ensured in this case that the first switching means is first opened or is opened, so as to avoid that the AC connection voltage is applied to only a part of the coil of the transformer. The same applies to any further switching means which establish a connection to the reference connection point from the transformer, in particular from further taps of the transformer.

In a further embodiment, a circuit arrangement is proposed, which is characterized in that the transformer has at least one fixed or variable further tap for providing at least one further tap voltage with respect to the reference connection point, which is smaller than the first tap voltage, and that in each case a further switching means is connected between the further tap and the reference terminal point to establish an electrical connection therebetween when closed. By using at least one other Tap can be adjusted according to different Windungsverhältnisse. Depending on the desired voltage to be applied to the consumer, a corresponding further tap can be electrically connected to the reference connection point. Again, the voltage change takes place at the consumer by a switching action between the transformer and the reference terminal point. Thus, also according to this embodiment, a circuit is avoided directly in the branch in which the consumer is connected. A switching of the voltage without interrupting the voltage at the consumer occurs, is thus feasible in a simple manner.

A further embodiment provides a circuit device which comprises at least two, preferably three, circuit arrangements according to the invention, the voltage connection points or the reference connection points being connected to one another. As a result, a plurality of circuit arrangements for driving a plurality of illumination means can be connected together to form a circuit device.

It is favorable if three circuit arrangements are provided and the circuit device is prepared for connection to a three-phase electrical system with three phases phase-shifted by approximately 120 ° to one another, and if the circuit device is connected to the three-phase system and switched on, the three voltage connection points are three electrical Lead phases and the reference connection points are connected to each other or the reference connection points lead three electrical phases and the voltage connection points are connected to each other.

The circuit device is thus provided for connection to a three-phase system. In one variant, the voltage connection points of the circuit arrangements used lead the three phases and the reference terminal points and thus the Bezugstransformatoranschlüsse are interconnected and connect according to one embodiment with the neutral conductor of an electrical supply network or connect to this.

This also means that the respective first switching means according to the invention have a common electrical node, namely the connected reference connection points. According to the other variant, the reference connection points lead the three phases and the voltage connection points are connected to one another in a common electrical node. In this case, the first switching means are thus arranged to the electrical phases and the first switching means thus have no common electrical node.

Preferably, the first switching means are coupled to each other for common switching, in particular combined to form a common switching means. This can be realized for example via a jointly controlled switching relay with a corresponding number of individual switches or by a mechanical coupling. Thus, the supply voltages for at least three illumination means can be reduced in a simple manner with a switching signal without having to fear voltage interruptions at the load.

A further embodiment provides to couple the second switching means for common switching with each other, Thus, the bridging of a part of the transformer and thus a direct application of the electrical connection AC voltage to the consumer, without voltage reduction for all circuits of the circuit device can be made common. This is particularly useful when voltage fluctuations in the electrical supply network occur, which usually affect all phases.

Another embodiment proposes that the further or some of the further switching means are coupled to each other for common switching. By further switching means a further voltage reduction of the voltage at the consumer is feasible. Such a voltage reduction can be used for example to reduce the brightness of a lighting means. When a circuit device having a plurality of circuit arrangements is used for adjusting a plurality of illumination means, there is Usually the desire to reduce the brightness for all lighting means in the same way. If the circuit arrangements of the circuit device are of the same type and dimensioning and of the connected illumination means, a similar brightness reduction of the illumination means can be achieved by the coupling of the further switching means. Of course, this requires the same voltage amplitude in the respective AC connection voltages. If, for example, two further switching means per circuit arrangement are used in a circuit device having three circuit arrangements for two brightness reduction stages, three switching means each can be coupled for a common brightness reduction stage.

Preferably, a circuit device according to the invention is prepared to be connected to a generally common three-phase system, as provided for example by conventional power supply networks. When the circuit device is connected to such a three-phase system and turned on, according to this embodiment, the voltage connection points guide this three-phase system, and the reference terminals are connected to each other and connected to a neutral of the three-phase system (neutral). Each transformer of a circuit arrangement is thus connected in each case between a phase and the neutral conductor. Accordingly, each consumer is connected to a first tap of a transformer and neutral. To lower the voltage, each first switch, in particular all the first switches coupled, is closed to switch each reference transformer terminal to the neutral to allow each transformer to act as a voltage divider and to correspondingly achieve a voltage drop for each connected load.

A method according to the invention, which uses a circuit arrangement according to the invention and / or circuit device according to the invention with a plurality of circuit arrangements, performs the following steps to drive at least one load connected between the first tap and the reference connection point: first, the power supply connected - circuit arrangement turned on, so that a voltage drops at the consumer, wherein the first switching means is opened. Then, a predetermined switch-on time is waited, which depends on the connected consumer in particular the connected lighting means. This turn-on time is at least as long as the connected lighting means or the like is required for high-voltage turn-on. Then then the first switching means can be closed and the voltage at the load is lowered thereby. When using a circuit device in a plurality of circuit arrangements and a plurality of connected consumers, these circuits are basically actuated synchronously in the reason.

According to a further embodiment, it is provided for a circuit device with three transformers that these are combined to form a three-phase transformer. In this case, a separate first tap and in each case a separate first, second and / or further or further switching means are provided for each phase.

Fig. 1

eine erfindungsgemäße Schaltungsanordnung in einer schematischen Schaltskizze,

Fig. 2

eine erfindungsgemäße Schaltungsanordnung gemäß einer weiteren Ausführungsform in einer schematischen Schaltskizze,

Fig. 3

eine erfindungsgemäße Schaltungsvorrichtung zum Anschluss an ein dreiphasiges Versorgungsnetz in einer schematischen Schaltskizze und
Fig.4 eine erfindungsgemäße Schaltungsvorrichtung gemäß einer weiteren Ausführungsform zum Anschluss an ein dreiphasiges Versorgungsnetz in einer schematischen Schaltskizze.

Embodiments of the present invention are explained in more detail below with reference to the accompanying figures. Show it:

Fig. 1

a circuit arrangement according to the invention in a schematic circuit diagram,

Fig. 2

a circuit arrangement according to the invention according to a further embodiment in a schematic circuit diagram,

Fig. 3

a circuit device according to the invention for connection to a three-phase supply network in a schematic circuit diagram and
Figure 4 a circuit device according to the invention according to a further embodiment for connection to a three-phase supply network in a schematic circuit diagram.

Fig. 1 1 shows a circuit arrangement 1 which has a voltage connection point 2 and a reference connection point 4 for connection to a phase L1 and a neutral conductor N, respectively. A transformer 6 is connected to a transformer voltage terminal 8 to the voltage connection point 2. A transformer reference terminal 10 is connected to the reference terminal 4 via a first switching means 12. The first switching means 12 is initially, as in Fig. 1 shown, opened.

Furthermore, the transformer 6 has a first tap 14, to which a consumer 16 is connected. The consumer 16 is also connected to the reference terminal 4.

In the illustrated case, essentially the entire voltage between the voltage connection point 2 and the reference connection point 4, ie the entire phase voltage, is applied to the load 16.

The first switching means 12 can be actuated via a first contactor 18 and thus can also be closed. When the first switching means 12 is closed, the transformer 6 with its transformer reference terminal 10 is electrically connected to the reference terminal 4 and is thus connected between the voltage terminal 2 and the reference terminal 4. Depending on the turns ratio of the transformer 6 in the first tap 14 relative to the total number of turns of the transformer 6, a corresponding partial voltage to the total voltage between the voltage connection point 2 and the reference connection point 4 is established at the first tap 14 substantially. This voltage is then applied to the load 16 and is less than the total voltage between the voltage connection point 2 and the reference terminal point 4. The voltage at the load 16 is thus reduced by closing the first switching means 12.

The circuit arrangement 201 of Fig. 2 According to a further embodiment substantially corresponds to the embodiment according to Fig. 1 and correspondingly includes a voltage terminal 202, a reference terminal 204, a transformer 206, a transformer voltage terminal 208, a transformer reference terminal 210, a first switching means 212, a first tap 214 and a load 216 and a first contactor 218 for driving the first switching means 212.

Basically added to the embodiment of the Fig. 1 is a second switching means 220 to make a direct contact between the voltage terminal 202 and the first tap 214 and thus the consumer 216. The second switching means 220 also has a second contactor 222 for opening and closing the second switching means 220. If the second switching means 220 is closed, the entire electrical connection alternating voltage is applied to the load 216.

Furthermore, the further switching means 224 is provided with a further contactor 226. With the aid of the further switching means 224, a further tap 228 can be connected to the reference connection point 204.

Thus, closing the further switching means 24 alters the effective effective turns ratio, which substantially determines the voltage level at the first tap 214, thereby reducing the voltage on the first tap 214, and thus the voltage on the load 216. The second switching means 220 is open. It should be noted that the second switching means 220 should only be closed when the first switching means 212 and the further switching means 224 are opened. Accordingly, an interconnection of the switching means directed thereto is proposed.

It should be noted that the transformer 6 according to Fig. 1 as well as the transformer 206 according to Fig. 2 are designed as autotransformers.

The basic mode of operation can also be formulated so that the transformer 6 or 206 to a lowering of the voltage at the load 16 and 216 by connecting the neutral terminal (of the transformer reference terminal 10 zw. 210) takes place. The supply voltage, namely the voltage between the voltage connection point 2 or 202 and the reference connection point 4 or 204 is connected to the terminals for the high voltage and the consumer 16 or 216 may be designed as a light source and at the terminals for the undervoltage of the transformer, namely be connected to the first tap 14 and 214, respectively. The connection for the neutral conductor of the transformer is initially not connected and at power-up almost the full supply voltage is applied to the lamps. After a start-up time or switch-on time adapted to the light sources, the neutral conductor of the transformer is connected. Due to the turns ratio of the winding parts, the voltage on the connected light source or the connected light sources decreases to the desired value. Since the lighting means (consumers 16 and 216) are permanently connected to the supply network via the upper winding part of the transformer, there is no interruption of the voltage in the switching moment.

If the permissible minimum voltage of the lamps is exceeded by mains voltage dips or mains undervoltages, the voltage reduction can be switched off in a simple manner via the first switching means 12 or 212 by an additional monitoring unit - which is not shown in the figures.

By leading out a plurality of neutral conductor connections, that is to say further taps 228 on the transformer 206, different turns ratios can be set. By switching the different further switching means 224 including the first switching means 212, a voltage reduction in several stages is possible.

In order to further increase the lighting security in the event of a fault, the second switching means 220 may be switched as a bypass to the transformer 206. This second switching means 220 and the second contactor 222 is locked by control technology against the first switching means 212 and further switching means 224.

Fig. 3 shows a circuit device 303 according to the invention, which essentially consists of three circuit arrangements according to Fig. 1 is composed. For a respective one of the phases L1, L2 and L3, a circuit arrangement 301U, 301V or 301W is essentially provided. Each circuit arrangement 301U, 301V, 301W has a first switching means 312 U, 312 V, 312 W, which, however, are controlled via a common contactor 318 and have a common node at the reference connection point 304.

Each circuit 301 U, 301 V, 301 W drives a load 316 U, 316 V, 316 W, which are connected together to the reference terminal 304. The transformers 306 U, 306 V, 306 W are combined into a three-phase transformer 306.

Incidentally, the basic mode of operation corresponds to Fig. 1 explained substantially synchronous to three phases according to the circuit device of Fig. 3 is executed. It is pointed out that the addition of the reference symbols U, V or W indicates the first, second or third phase.

Fig. 4 shows a further embodiment of a circuit device 403, which consists essentially of three circuit arrangements according to the circuit arrangement of Fig. 2 are interconnected for use in a three-phase system. Accordingly, the circuit device 403 of the Fig. 4 opposite to the circuit device 303 of Fig. 3 three second switching means 420 U, 420 V and 420 W on. These three second switching means are controlled jointly via a common second contactor 422.

In addition, the circuit device 403 has three further switching means 424 U, 424 V and 424 W, which are connected together via a common further contactor 426. Otherwise, the mode of operation results from the description of the individual circuit arrangements 1 according to FIG Fig. 1 or 201 according to Fig. 2 and the description of the circuit device 303 of FIG Fig. 3 ,

1.

Schaltungsanordnung: 1, 201, 301, 401

2.

Spannungsanschlusspunkt: 2, 202, 302, 402

3.

Schaltungsvorrichtung: 303, 403

4.

Bezugsanschlusspunkt: 4, 204, 304, 404

6.

Transformator: 6, 206, 306, 406

8.

Transformatorspannungsanschluss: 8, 208, 308, 408

10.

Transformatorbezugsanschluss: 10, 210, 310, 410

12.

Erstes Schaltmittel: 12, 212, 312, 412

14.

Erster Abgriff: 14, 214, 314, 414

16.

Verbraucher: 16, 216, 316, 416

18.

Erstes Schütz: 18, 218, 318, 418

20.

Zweites Schaltmittel: 220, 420,

22.

Zweites Schütz: 222, 422

24.

Weiteres Schaltmittel: 224, 424

26.

Weiteres Schütz: 226, 426

28.

Weiterer Abgriff: 228, 428

The reference numerals for all illustrated embodiments are listed below for the sake of completeness, wherein the indices U, V and W, respectively, which characterize the first, second and third phase have been omitted for the sake of clarity:

1.

Circuit arrangement: 1, 201, 301, 401

Second

Voltage connection point: 2, 202, 302, 402

Third

Circuit device: 303, 403

4th

Reference connection point: 4, 204, 304, 404

6th

Transformer: 6, 206, 306, 406

8th.

Transformer voltage connection: 8, 208, 308, 408

10th

Transformer reference connection: 10, 210, 310, 410

12th

First switching means: 12, 212, 312, 412

14th

First tap: 14, 214, 314, 414

16th

Consumers: 16, 216, 316, 416

18th

First contactor: 18, 218, 318, 418

20th

Second switching means: 220, 420,

22nd

Second contactor: 222, 422

24th

Further switching means: 224, 424

26th

Another contactor: 226, 426

28th

Another tap: 228, 428

Claims (13)

Circuit arrangement (1) for uninterrupted voltage drop of an electrical AC voltage to a consumer (16), in particular a lighting means, with
at least one voltage connection point (2) and a reference connection point (4) for providing an electrical connection AC voltage therebetween and
a between the voltage terminal point (2) and the reference terminal point (4) arranged transformer (6), in particular autotransformer with
a transformer voltage connection (8) connected to the voltage connection point,
a transformer reference terminal (10) connected via a first switching means to the reference terminal (4) and
a fixed or variable first tap (14) for providing a first tap voltage relative to the reference terminal (4),
wherein the circuit arrangement (1) is prepared to close the first switching means (12) thereby to reduce, in operation, the first tap voltage at the load (16) when connected between the first tap (14) and the reference terminal point (4). connected. Circuit arrangement (1) according to claim 1, further comprising a switch-on means for switching on the circuit arrangement (1). Circuit arrangement (1) according to Claim 1 or 2, characterized in that a second switching means (220) is connected between the voltage connection point (2) and the first tap (14) in order to establish an electrical connection therebetween in a closed state. Circuit arrangement (1) according to one of claims 1-3, characterized in that the transformer (6) has at least one fixed or variable further tap (28) for providing at least one further tap voltage with respect to the reference connection point (4), which is smaller than the first tap voltage, and each further switching means (24) connected between the further tap (28) and the reference terminal point (4) to establish an electrical connection therebetween when closed. Circuit device (3) comprising at least two, preferably three circuit arrangements (1) according to one of the preceding claims, wherein the voltage connection points (2) or the reference connection points (4) are interconnected. Circuit device (3) according to claim 5, characterized in that three circuit arrangements (1) are provided and the circuit device (3) is prepared for connection to a three-phase electrical system with three phases phase-shifted by approximately 120 ° to each other, and in that when the circuit device (3) connected to the three-phase system and turned on,
the voltage connection points (2) lead three electrical phases and the reference connection points (4) are connected to each other or
the reference connection points (4) carry three electrical phases and the voltage connection points (2) are interconnected. Circuit device (3) according to claim 5 or 6, characterized in that the first switching means (12) are coupled to each other for common switching. Circuit device (3) according to any one of claims 5-7 and with a plurality of circuit arrangements (1) according to claim 3 or 4, characterized in that the second switching means (20) are coupled together for common switching, in particular to a common switching means are combined. Circuit device (3) according to any one of claims 5-8 and with a plurality of circuit arrangements (1) according to claim 4, characterized in that the or some of the further switching means (28) are coupled together for common switching. Circuit device (3) according to any one of claims 6-9, characterized in that , when the circuit device (3) is connected to the three-phase system and turned on, the three voltage connection points (2) guide the three phases of the three-phase system and all reference connection points (4) are connected to a neutral of the three-phase system. Circuit device (3) according to any one of claims 6-10, characterized in that the transformers (6) are combined to form a 3-phase transformer. A method of driving at least one electrical load (16), in particular a lighting means, using a circuit arrangement (1) according to one of claims 1-4 and / or a switching device (3) according to any one of claims 5-10, wherein the at least one consumer (16) is connected between the first tap (14) and the reference terminal (4), comprising the steps of: Switching on the circuit arrangement (1) or the circuit device (3) so that a voltage drops across the load (16), the at least one first switching means (12) being open, Waiting for a predetermined on-time and Closing the at least one first switching means (12) for lowering a voltage at the load (16). The method of claim 11, further comprising at least one of the steps: Closing the second switching means (20) to increase the voltage at the load (16), Closing at least one of the further switching means (28) for lowering the voltage at the load (16) and Changing the first switching means (12) or at least one of the first switching means (12) and / or the at least one further tap (28) or at least one of the further taps (28) to increase the voltage at the load (16) or lowering, wherein the second switching means (220) or one of the second switching means (220) is closed before changing and reopened after completion of the changing.

Images