DE3744436A1 - Variable transformer - Google Patents

Abstract

In the case of a variable transformer, especially for test installations, having a transformer core, a primary winding and a single-layer variable winding with which contact can be made and along which at least one current pick-off can be displaced relative to the variable winding, making contact with it, at least one end of the variable winding (3) is connected to at least one short-circuiting ring (4), and a further current pick-off (6) is provided which can be moved relative to the short-circuiting ring (4) and makes contact with it (Figure 1). <IMAGE>

Description

The invention relates to a variable transformer according to the Preamble of claim 1.

Such are particularly the case in laboratory and test field operations small inexpensive units desired. Losses and Efficiency play a subordinate role in Contrast to the price-performance ratio and to casual performance in short-term operation.

Variable transformers for feeding AC voltage test systems are almost always capacitively loaded. To the one large high-voltage test transformers Thoma regulator common. The one compared to airless ones Variable transformers large open circuit current of the Thoma regulator is not a disadvantage with this use. You can do that Magnetizing current as part of the inductive current that is desired for compensation, i.e. the The air gap of the Thoma regulator has relief the same for the entire feed system beneficial effect as a correspondingly dimensioned Primary compensation choke. This choke can, for example be a short-circuit ring in the variable transformer is installed. So although the electrical effect of the Air gap when using the Thoma regulator as Variable transformer for AC voltage test systems because of  of the large magnetizing current and also because of the Harmonic freedom mostly due to low flux density is advantageous, the air gap has a hard time here too outweighing disadvantages. For example, reference is made here auf Seifert: "Variable transformers", Dr. H. Hüthig Verlag, Heidelberg, 1971.

These disadvantages are:

• - complicated and therefore expensive core;
• - Magnetic forces and noise in the event of asymmetries the air gap;
• - despite the use of pole shoes, d. H. despite ver enlargement of the iron cross section near the This section of the magnetic circuit has an air gap such a large magnetic resistance that the Use of highly permeable core materials for the whole not worth the magnetic core;
• - Because of the air gap, the core is used as a shell type executed, d. H. with three-phase current, three single-phase Transformers are used.

These disadvantages are intended with the present invention be avoided. This is indicated by the Claim 1 features achieved.

The short circuit ring with pantograph replaces the Air gap and the outside of the magnetic circuit Slip ring of the Thoma regulator.

Further features of the present invention are in claimed the subclaims.

Further advantageous details of the invention emerge themselves from the drawing.

Fig. 1 shows the construction principle of the present invention.

The actuating winding 3 surrounding the leg 1 of a transformer core 2 is connected at one end to the short-circuit ring 4 and can be rotated relative to the current collectors 5 and 6 . The primary winding and complete magnetic circuit of the variable transformer according to the invention are not shown in the drawing.

The small diameter d of the actuating winding 3 and the large diameter D of the short-circuit ring 4 indicate the desired tight or loose coupling with the primary winding. The representation of the short-circuit ring 4 as a thin-walled, cylindrical section is intended to show that the short-circuit ring 4 has a large inductance. In contrast to the flat short-circuit ring 4 (cylindrical section), the actuating winding 3 is made of edged bare conductor material, for example on a copper profile, and can in particular - like the Thoma controller - be arranged on a rotatable insulating cylinder. The end of the actuating winding 3 , however, is not like the Thoma controller together with the insulating cylinder leads through an air gap from the magnetic circuit, but is connected to the short-circuit ring 4 , which comprises the main flux of the magnetic circuit, namely the leg 1 . A pantograph 5 grinds - as in the Thoma controller - preferably on the outside of the bare control winding 3 and is guided by the helix of the control winding 3 . Another pantograph 6 grinds on the bare circumference (outside, inside, above or below) of the short-circuit ring 4 .

In a circle portion of the short-circuit ring 4 flows the (geometric) sum, in the other the (geometrical) difference between loop current and active current, wherein the current is denoted by circulating current according to the voltage interturn and impedance of the short-circuit ring 4 in the short-circuit ring 4 flows and with useful flow the current in the control winding 3 . The length of these two sections depends on the position of the pantograph 6 relative to the connection of the actuating winding 3 on the short-circuit ring 4th The cross section of the short-circuit ring 4 is dimensioned accordingly to the current load for a multiple of the nominal current of the actuating winding 3 and the impedance of the short-circuit ring 4 selected so that the apparent power of the short-circuit ring 4 on the one hand and the voltage drop in the useful current path on the section of the short-circuit ring 4 on the other hand are not too large becomes.

With the Thoma regulator, the voltage change as a function of the angle of rotation would be constant with a circular core cross section. When the current is drawn by means of the short-circuit ring 4 , on the other hand, the open circuit voltage changes in principle as a result of passing through a turn - step-like, ie the voltage tapped is only proportional to the angle of rotation on average. In most application cases, this is not a problem because the deviations can be easily corrected in practice.

In principle, all circuits are executable, as with other variable transformers. In the economy circuit and rotatable actuating winding 3 at least 2 short-circuit rings are required, which is not shown in the drawing.

In contrast to the Thoma control which - as mentioned - as Sheath type can be executed with the air gapless variable transformer according to the invention any usual core form are used, for example core or jacket  type for single-phase transformers or three-legged cores in three-phase transformers.

If a particularly high short-circuit strength is required, fixed actuating winding 3 with short-circuit ring 4 and rotating pantograph contacts 5 and 6 are advantageous, which are usually designed so that the contact pressure increases due to the short-circuit current ver.

This variant is also advantageous to use for the economy circuit. With a fixed actuating winding 3 one comes out with a short circuit ring 4 even with economy circuit.

The transmission of the rotary movement to the actuating winding 3 and the short-circuit ring 4 or to the current collectors 5 or 6 is expediently carried out by means of plastic toothed rings.

In principle to compensate for variable transformers occurring ampere-turn asymmetry, i.e. for ver reduction of the leakage flux and its disadvantages (short final voltage, so the difference between idle and Load voltage, eddy currents, d. H. Warming more conductive Construction parts, force effects in the event of a short circuit) the usual measures are applicable, such as Schubwick lungs, the slotted thrust being a special case winding cylinder, which also has the function electromagnetic shielding and mechanical ver Take over the strengthening of the insulating tube of the control winding can.

The centerpiece of the variable transformer according to the prior invention is in addition to the actuator winding known from the Thoma regulator the short-circuit ring 4th

The short-circuit ring 4 practically takes the place of the air gap, ie the variable transformer according to the prior invention has the operating behavior of the Thoma regulator.

In the following, this should be based on the expedient here Four-pole equivalent circuit diagram are explained in more detail:

The impedance of the short-circuit ring 4 is parallel to the much larger magnetization impedance and therefore determines the open-circuit current, ie it represents the open-circuit impedance. The terms "short-circuit impedance" and "leakage flux" are avoided in the description of the short-circuit ring 4 to avoid confusion with the leakage impedance exclude the equivalent circuit diagram that determines the load and short circuit behavior of the transformer. The magnetic field of the short-circuit ring 4 brings with it the structural problems of a stray field (eddy currents, heating and the effects of force in conductive structural parts) and the part of the impedance of the short-circuit ring 4 which is dependent on the angle of rotation and which is flowed through by the two parts of the secondary current which are also dependent on the angle of rotation. is also part of the stray impedance of the variable transformer.

To understand the operating behavior, however, it is sufficient and useful to take the short-circuit ring 4 - as usual - as a choke between the primary terminals, because the air gap of the Thoma controller is taken into account in the same way by taking the magnetizing current into account as part of the primary current.

Corresponding to the winding voltage (for example in the order of 10 V for the Thoma controller, here correspondingly larger for the air gapless transformer core 2 ), the impedance of the short-circuit ring 4 must be made large enough to keep the magnetic field and the power loss of the short-circuit ring 4 within tolerable limits, what can be achieved either by the formation of the short-circuit ring 4 as a resistance ring with cooling fins for small or as a reactance ring with core in large versions.

A combination of these measures only makes sense if the reactance and resistance in the to bring the same order of magnitude. This is in a special case possible, for example by using ferromagneti chemical resistance material, either for the Contact path of the pantograph is used or is connected with contact material.

Figs. 2 to 4 show embodiments of short-circuit rings 4 as Reaktanzringe. Since the inductance of the short-circuit ring 4 by selecting the dimensions can not be made large enough alone (space required for the possible large, thin-walled and high ring in the core window) of the copper conductor 4 'of the short-circuit ring 4 is, for example, as shown in FIG. 2 as surrounded by a magnetic core 7 that only one circumferential gap 13 remains free for the narrow track of the pantograph 6 . The magnetic core 7 can ge according to the further embodiment according to FIG. 3, for example, from individual, provided with a slot 8 ferrite fittings 9 , which is placed on the short-circuit ring 4 ge and for example by means of elastic inserts (not shown in the drawing) are jammed. Ver one turns shown in FIG. 4 is a second annular, connected to the current collector 6 magnetic core part 12 for covering the grinding path of the current collector 6, the magnetic flux of the short-circuit ring 4 is driven out of highly permeable material up to the air gap 10 in a magnet core 7. This air gap 10 allows the relative movement between the short-circuit ring 4 and Stromab subscriber 6 , namely between the magnetic core parts 11 and 12 , which may consist, for example, of individual ferrite fittings 9 - as shown in FIG. 3.

As already indicated, it is fundamentally possible and, in certain exemplary embodiments, also necessary to provide more than one short-circuit ring 4 . As already mentioned, at least two short-circuit rings 4 are required when using the economy circuit and rotary actuating winding 3 .

Even if the variable transformer according to the invention before for test systems, preferably for feeding in AC test equipment is used, so is however, its use in this area of application is not limited.

Claims (12)

1. variable transformer, in particular for test systems, with a transformer core, a primary winding and a single-layer contactable actuating winding, along which at least one pantograph is adjustable relative to the actuating winding, contacting it, characterized in that at least one end of the actuating winding ( 3 ) with at least one short-circuit ring is connected (4) and another current collector (6) is provided which is movable relative to the short-circuit ring (4) and contacts it. 2. Variable transformer according to claim 1, characterized in that the short-circuiting ring ( 4 ) is surrounded by an annular gap ( 13 ) for the further current collector ( 6 ) having an annular magnetic core ( 7 ). 3. Variable transformer according to claim 2, characterized in that the magnetic core ( 7 ) from individual, lined up a slot ( 8 ) having ferrite shaped pieces ( 9 ) be and the slots ( 8 ) form the peripheral gap ( 13 ) in a lined up state. 4. Variable transformer according to claim 2 or 3, characterized in that the magnetic core ( 7 ) has an air gap ( 10 ) by an annular or disc-shaped part ( 12 ) of the same from the rest of the core part ( 11 ) through the air gap ( 10 ) is separated . 5. Control transformer according to one of claims 2 to 4, characterized in that the path of the short-circuit ring ( 4 ) which is free to draw current is covered by an annular magnetic core part ( 12 ) via an air gap ( 10 ), the further current collector ( 6 ) covering the air gap ( 10 ) and the annular magnetic core part ( 12 ) penetrates. 6. Variable transformer according to one of claims 1 to 6, characterized in that the short-circuit ring ( 4 ) consists of resistance material and is seen with cooling fins ver. 7. Variable transformer according to one of claims 1 to 6, characterized in that the short-circuiting ring ( 4 ) has a rectangular cross section and forms a cylindrical section. 8. Variable transformer according to one of claims 1 to 7, characterized in that the winding spacing (diameter D) of the short-circuit ring ( 4 ) from the leg ( 1 ) of the transformer core ( 2 ) is large in relation to the winding spacing (diameter d) of the actuating winding ( 3 ) from the leg ( 1 ) of the transformer core ( 2 ). 9. Variable transformer according to one of claims 1 to 8, characterized in that the actuating winding ( 3 ) and the short-circuit ring ( 4 ) on the transformer core ( 2 ) are fixedly arranged and that the actuating winding ( 3 ) contacting current pantograph ( 5 ) one of the pitch of the control winding ( 3 ) corresponding screw line and the short-circuit ring ( 4 ) contacting further pantographs ( 6 ) are movable on a circular path. 10. Variable transformer according to one of claims 1 to 8, characterized in that the actuating winding ( 3 ) and the short-circuit ring ( 4 ) together around one leg ( 1 ) of the transformer core ( 2 ) are rotatable and the assigned pantographs rigid ( 6 ) or are only movable ( 5 ) in the axial direction of the positioning winding ( 3 ). 11. Variable transformer according to one of claims 1 to 10, characterized in that the actuating winding ( 3 ) consists of an upright wound conductor. 12. Variable transformer according to one of claims 1 to 11, characterized in that the transformer core ( 2 ) is formed without an air gap.