DE4317533A1 - Variable-ratio transformer - Google Patents

Abstract

The subject matter of the invention is a variable-ratio transformer which is designed as a multiple limb transformer. This variable-ratio transformer furthermore has at least one secondary winding which is fitted on a first core limb, a plurality of primary windings which are fitted on at least one further core limb, and a control unit for determining the winding voltages. In order to ensure reliable isolation of the mains side, the output side and the control side and in order to reduce the circuit complexity required, the invention stipulates that the magnetic flux in that core limb (S2) which is assigned to the secondary is equal to the geometric sum of the magnetic fluxes in all the core limbs (S1, S3) assigned to the primary, that each primary winding (N1, N3) consists of at least one elementary winding, that mains voltage is applied to at least one primary winding (N1) and the input voltages of the other primary windings (N3) are determined by means of an additional group of source windings (N1.1 to N1.n) which are magnetically coupled to the primary winding which is connected to the mains voltage, and that the control unit (St) is designed for amplitude-controlled and/or phase-controlled application of voltage to the primary windings (N1, N3). The amplitude control is preferably carried out step by step, each primary winding (N3) which is not connected to the mains voltage being assigned a phase-shifter stage composed of four switches (Si.k) which form a bridge, one of whose diagonals ... to the corresponding ... Original abstract incomplete. <IMAGE>

Description

The invention relates to a variable transformer in the preamble of claim 1 specified features.

From DE 32 14 973 C2 is a variable transformer with at least one least an iron core arranged primary and magnetic with it coupled secondary winding known, in which also an electronic Control to achieve an at least approximately continuously adjustable Secondary voltage is provided. The primary side of this well-known position transformators is connected to the network and its secondary side consists of galva nically separate windings with number of turns in the ver ratio of an increasing, unlimited number sequence. The one in the single Individual voltages induced by windings can be controlled via electronic Connect the switch in the same or opposite direction so that with the Voltage of the single winding with the smallest number of turns as voltage jump voltages between the voltage value zero and the voltage limit value can be set when all individual windings are connected in series. Should the known variable transformer have a high output power or a emit large output current, the electronic ones used must also Switches are designed for high power or high currents, which the required technical effort increases and thus the production costs drives up.

From DE 34 22 961 C2 is an adjustable transformer arrangement voltage known, the at least one secondary winding and a plurality of has individual stages forming primary windings, which separate cores are assigned and which are in line with them and by means of electronic switches which can be controlled by an electronic control unit and let it switch off. All primary windings are known to this th transformer assembly connected to the network, and therefore there are none  galvanic isolation between the control side with the primary windings on the one hand and the network on the other. An adjustment is also required the electronic switch on the input side and therefore in most Cases to the network. Also in this known transformer arrangement ge Manufacturing is very complex, since either several Transfor mators or a secondary winding distributed over the various cores required are.

The invention is therefore based on the object, a Stelltransfor mator to create a galvanic isolation from the network, output side and control side can ensure an adjustment of control voltages and control currents to existing switches and is inexpensive can be made.

The object is achieved according to the invention by a Variable transformer, as specified in claim 1; beneficial Refinements and developments of the invention result from the Subclaims.

A variable transformer according to the teaching of the invention is in principle a multi-leg transformer, in which the magnetic flux in the leg the secondary side by the geometric sum of the magnetic fluxes in all legs of the primary windings are formed on one of the primary the mains voltage is present and the input voltages of the others Primary windings by means of an additional and with the network winding get magnetically coupled group of windings (source windings) , each of the primary windings consists of at least one winding (elementary windings) and the chips applied to the primary windings tions by means of the control unit amplitude and / or phase controlled are.

In a modification of this basic design, all primary wick can lungs are connected to the network; in this case the additional group of windings.  

By foregoing either amplitude control or Phase control for the voltages applied to the primary windings the overall construction can be particularly simplified.

A step-by-step amplitude control on the primary windings placed voltages leads to an increase in the overall efficiency of the Transformer.

For further explanation of the invention and its special features and advantages is now referred to the drawing, in which as game a three-leg transformer is illustrated; show in the Drawing in detail:

Fig. 1 shows a first circuit design for the invention,

Fig. 2 shows a second circuit design of the invention,

Fig. 3 shows a third circuit embodiment of the invention and

Fig. 4 possibilities for controlling the control windings by means of changers.

In Fig. 1, a variable transformer is shown, which is designed as a three-leg transformer with three legs S1, S2 and S3 magnetically interconnected via yoke. The magnetic flux in the second leg S2, the middle leg, is the geometric sum of the magnetic fluxes in the two peripheral legs, the first leg S1 and the third leg S3. So it is a magnetic addition.

The mains voltage is supplied via an amplitude and pha senansteuerungseinheit, which is part of a control unit St, to a first Primary winding, the network winding, which consists of several elementary windings N1-1 to N1-k and is applied to the first leg S1. To one second primary winding N3 on the third leg S3 are through the Amplitude and phase control unit the voltages of an additional Group of windings N1.1 to N1.n, the source windings, created  are also applied to the first leg S1 and thus magnetic Kopop with the elementary windings N1-1 to N1-k of the first primary winding pelt are.

By changing the amplitude and / or phase of the different Voltages applied to primary windings allow the voltages in on the second leg S2 applied secondary windings N2.1 to N2.m. Taxes. Are z. B. the amplitudes of the voltages in the primary windings N1-1 to N1-k and N3 are the same size, but phase 180 ° relative to each other shifted, the output voltage on the secondary windings N2.1 to N2.m is zero. Are the voltages in the primary windings equal and not out of phase with each other, the output voltage takes its maximum value. The secondary windings N2.1 to N2.m are made as needed either connected in series or in parallel. These switches take place either in the de-energized state or during operation. It is it is possible to optimize the power losses in the transformer.

In another embodiment of the transformer, the additional windings N1.1 to N1.n on the first leg S1, the Source windings, and the primary winding N3 on the third leg S3 is also connected to the network by the amplitude and phase control unit connected.

In a further embodiment, the primary windings applied voltages only phase-controlled. That has no effect on the Control area, but simplifies construction. For easy application two primary windings are sufficient.

In Fig. 2 another embodiment is shown, in which the variable transformer is again formed as a three-leg transformer with two edge limbs S1 and S3 and a central leg S2. The input voltage denoted by U1 is on a primary winding N1 on the first leg S1 and generates a magnetic flux Φ1 therein. This magnetic flux induces in additional windings N1.1 to N1.n on the edge limb S1 voltages that form a series of numbers. A voltage is applied to the primary winding N3 on the third leg S3, the amplitude of which is determined on the one hand by the turns ratio of the additional windings N1.1 to N1.n and the primary winding N1 on the first leg S1 and on the other hand by the number of closed switches S1.1 to S1.n is determined and the phase of which results from the state of the switches S0.1 to S0.4. If switches S0.2 and S0.3 are closed and switches S0.1 and S0.4 open, the voltage on winding N3 is in phase with voltage U1. If switches S0.2 and S0.3 are open and switches S0.2 and S0.4 are closed, the voltage on winding N3 is in phase opposition (phase shift 180 °) to voltage U1. The voltage in winding N3 also creates a magnetic flux Φ3. Therefore, the magnetic flux Φ2 in the central leg S2 is equal to the algebraic sum of the magnetic fluxes in the peripheral legs S1 and S3. The magnetic flux Φ2 in the middle leg S2 induces a voltage U2 in the output winding, the secondary winding N2 on the middle leg S2, the value of which is therefore determined by the algebraic sum of the magnetic fluxes Φ1 and Φ3. By switching switches S1.1 to S1.n and switches S0.1 to S0.4, the output voltage U2 of the transformer can be controlled in stages. If the switches S0.2 and S0.3 are closed and the switches S0.1 and S0.4 open, then the output voltage U2 is reduced from the minimum value by switching the switches S1.1 to S1.n (switch S1.1 closed to S1.n, switches S2.1 to S2.n open) up to a voltage that is only determined by the turns ratio N2 / N1 (switches S1.1 to S1.n open, switches 2.1 to S2.n closed) , ge controlled. If switches S0.2 and S0.3 are open and switches S0.1 and S0.4 are closed, then the output voltage U2 is switched by the switches S1.1 to S1.n from the voltage caused by the turns ratio N2 / N1 is determined (switches S1.1 to S1.n open, switches S2.1 to S2.n closed), up to the maximum value (switches S1.1 to S1.n closed, switches S2.1 to S2.n open ) controlled. The switching of the switches is done by a control unit, which is not specifically shown in FIG. 2. If a switch S1.i is closed, the corresponding switch S2.i must be open and vice versa. The switching of the switches does not necessarily have to take place in the zero crossing of the current in the winding N3; however, this is preferred to reduce switching losses.

A further exemplary embodiment is shown in FIG. 3, in which the variable transformer is again designed as a three-leg transformer with three legs S1 to S3. However, in this example, each of the individual source windings N1.1 to N1.n has its own phase reversal stage. The voltage at each individual source winding when the voltage is formed in the winding N3 on the third leg S3 either with the sign "+" (switches Si.1 and Si.4 closed and switches Si.2 and Si.3 open) or with the sign "-" (switches Si.1 and Si.4 open and switches Si.2 and Si.3 closed) cooperate or fail completely (switches Si.1 and Si.3 closed and switches S1.2 and Si. 4 open). The output voltage U2 is again determined by the algebraic sum of the magnetic fluxes Φ1 and Φ3 in the marginal limbs S1 and S3.

The number of turns of the individual primary control windings in the off exemplary embodiments of FIG. 2 and FIG. 3 form any number series. In further exemplary embodiments, these numbers of turns follow the ratio sequences 1: 2: 4: 8: 16: 32 etc. or 1: 3: 9: 27: 81 etc.

3 are only schematically shown, the switches shown in FIG. 2 and FIG., May be formed as an anti-parallel-connected transistors or other semiconductor devices as mechanical switches, as relays or contactors, as an anti-parallel connected thyristors, or triacs.

In a further embodiment using mechanical switches or relays or contactors, these are designed as changeover contacts, as is illustrated in FIG. 4.

In yet another embodiment, each switch is an entity from an electromechanical switch such as a relay or contactor and off a semiconductor switch connected in parallel (antiparallel connected Thyristors, triacs, anti-parallel transistors or other half conductor components). The electromechanical switch then works statically, which has a small on resistance and the semiconductor becomes dynamic effective switch that has short switching times.  

In a further embodiment, the control unit is a micro controller or designed as a microprocessor with peripherals. Doing so the output voltage is set digitally, and the switches are used by the parallel ports of the microcontroller controlled. Driving the switches is designed so that the actual closing or opening of the switches in the Current zero crossing occurs; the delay times become software considered.

In a preferred embodiment, the transformer is used as a control trans formator operated. The voltage or current on the output side measured and converted into a number using an A / D converter. Of the Microcontroller constantly compares the actual and target values of the output variable and calculates the required states of the switches.

In its normal execution, the subject of the invention is a Variable transformer, which is designed as a multi-leg transformer. This variable transformer also has at least one on a first one Secondary winding applied to core leg, a plurality of at least a further core leg applied primary windings and a tax unit for determining the winding voltages.

For reliable separation of the network side, output side and control side and reduction of the required circuitry is provided that the Magnetic flux in the core leg assigned to the secondary side is equal to that geometric sum of the magnetic fluxes in all assigned to the primary side The core leg is that each primary winding consists of at least one elementary winding exists that at at least one primary winding mains voltage lies and the input voltages of the other primary windings by means of a additional group of with the primary winding connected to the mains voltage magnetically coupled source windings are determined and that the tax unit to an amplitude and / or phase controlled voltage system the primary windings is designed.  

The amplitude control is preferably carried out in stages, with each a primary phase not connected to the mains voltage is assigned to four switches that form a bridge, one of which is diagonal connected to the corresponding primary winding while its other Diagonal with the source windings over a group of switches with two Switches per elementary winding and one of those not connected to the mains voltage Primary windings is connected. Each source winding is two scarves ter assigned and the first pole of the first switch with the first wick Connection, the second winding connection with the first pole of the second Switch, the second pole of which with the second pole of the first switch second pole of the switch of the first winding with the first point of the two th diagonal of the phase reversing stage, the second pole of the switch of the not Main windings connected to the mains voltage with the second connection of each Weil's previous winding and the second connection of the last winding connected to the second point of the second diagonal of the phase reversal stage.

Claims (17)

1st variable transformer with

• a core with several legs,
• - At least one secondary winding applied to a first core leg,
• - A plurality of brought up at least one further core leg primary windings and
• a control unit for determining the winding voltages,

characterized,
that the magnetic flux in the core leg (S2) assigned to the secondary side is equal to the geometric sum of the magnetic fluxes in all core legs (S1, S3) assigned to the primary side,
that each primary winding (N1, N3) consists of at least one elementary winding,
that mains voltage is present at at least one primary winding (N1-1 to N1-k) and the input voltages of the other primary windings (N3) by means of an additional group of source windings (N1.1 to N1.n) magnetically coupled to the primary winding connected to the mains voltage are determined and
that the control unit (St) is designed for an amplitude and / or phase-controlled voltage system on the primary windings. 2. Transformer according to claim 1, characterized in that all primary windings are connected to the mains voltage. 3. Transformer according to claim 1, characterized in that only one primary winding (N1-1 to N1-k) has mains voltage and the input voltages for the other primary windings (N3) are determined by the control unit (St). 4. Transformer according to one of claims 1 to 3, characterized in that the primary windings not connected to the mains voltage after Autotransformer principle are formed.   5. Transformer according to one of claims 1 to 4, characterized in that the voltages applied to the primary windings are only phase-tight controls are. 6. Transformer according to one of claims 1 to 4, characterized in that the voltages applied to the primary windings (N1, N3) amplify are controlled by the clock and their phase shift compared to the network voltage is 0 or 180 °. 7. Transformer according to claim 6, characterized in that a stepwise amplitude control is provided, each primary winding (N3) not connected to mains voltage one phase wender stage of four switches is assigned to a bridge form one diagonal with the corresponding primary winding is connected, while its other diagonal with the Quellenwick lungs (N1.1 to N1.n) via a group of switches with two Switches per elementary winding on the source side and one of the not primary windings connected to the mains voltage and the first pole of the first switch with the first winding connection, the second winding connection with the first pole of the second scarf ters, its second pole with the second pole of the first switch and the second pole of the switch of the first winding with which he most point of the second diagonal of the phase reversal stage, the second Poles of the switches of the primary winding not connected to the mains voltage lungs with the second connection of the previous winding and the second terminal of the last winding with the second point the second diagonal of the phase reversing stage are connected. 8. Transformer according to claim 6 or 7, characterized in that every elementary development of the source side for everyone is not connected to the network voltage primary winding assigned a phase inverter stage is. 9. Transformer according to claim 7 or 8, characterized in that the number of turns of the elementary windings on the source side below are in a ratio of 1: 2: 8: 16: 32 etc.   10. Transformer according to claim 7 or 8, characterized in that the number of turns of the elementary windings on the source side below are in a ratio of 1: 3: 9: 27: 81 etc. 11. Transformer according to one of claims 7 to 10, characterized in that the switches as relays or contactors or as mechanical switches are trained. 12. Transformer according to one of claims 7 to 10, characterized in that instead of two switches (one break contact and one make contact) per winding Changer is provided. 13. Transformer according to one of claims 7 to 10, characterized in that that the switches are switched by anti-parallel thyristors, triacs, anti-parallel connected transistors or other semiconductor construction elements are formed. 14. Transformer according to one of claims 7 to 10, characterized in that each of the switches consists of a relay or contactor, the one Semiconductor switches (anti-parallel thyristors, triacs, anti-parallel connected transistors or other semiconductor construction elements) is connected in parallel. 15. Transformer according to one of claims 1 to 14, characterized in that the control unit (St) as a microcontroller or as a microprocessor is trained. 16. Transformer according to one of claims 1 to 15, characterized in that that it is operated as a control transformer.