DE1193592B - Control transformer with flux drainage and multi-turn control winding - Google Patents

Description

Control transformer with flux displacement and multi-turn control winding Control transformers are known which operate on the principle of flux displacement. With them you have z. B. special taps on the catchy control winding of the windings provided and led out to a separate contact track in this way, that the discharges are only linked with partial flows, so that in the event of a short circuit between two taps, the partial flow linked with these takes the path of others Partial rivers is pushed away. Although this design results in a reliable limitation of the short-circuit current between two taps, but is for small regulating transformers too expensive because of the additional contact path required.

Furthermore, there is a flux displacement transformer with a single-start regulating winding known, in which the control winding itself is used as a contact track. The turns of the regular winding wrap one after the other around the middle limb and alternately one the outer thighs, in which the river displacement takes place. The contact slides across these combined turns. But even this arrangement is difficult in the production, because the alternating looping of the middle leg and the outer leg is not possible with normal winding machines.

It is also known, the control winding of a control transformer multi-thread without flux displacement, whereby the short circuits that the movable Causes contact in the winding, limited by resistances or impedances, which are switched into the supply lines to the partial windings. The resistances or impedances, however, mean additional effort and additional losses.

The invention relates to a new type of control transformer with river displacement, which avoids the disadvantages of the aforementioned systems. It it is assumed that the transformer has m separate return legs and that the middle leg carries the control winding from which the voltage of the turn to turn is removed by a contact without interruption in such a way that this Contact touches a maximum of m, preferably two adjacent turns. According to the The invention is the control winding in a manner known per se as a multi-turn winding executed with m gears, and the flow displacement in the yoke legs is achieved in that the leads to the partial windings outside the iron core one after the other through the interstices between the yoke legs are performed and the partial windings are directly parallel through these leads be switched.

The control winding can be carried out in a simple manner, since it only has the Middle leg wraps around. A web can also easily be made shiny on it, on which a contact can slide. The partial windings of the normal winding are open the middle leg out side by side in the manner of a multi-thread screw. However, the leads to them may not be applied next to one another in the same way otherwise the contact of two adjacent turns of different partial windings due to the moving contact a complete short circuit with correspondingly high Short-circuit currents would result. Only when, according to the invention, the supply lines to the partial windings in the manner described through the spaces between the return legs are performed, flow displacement can arise with the known Effect of damping the short circuit. If now the rule contact is two adjacent Touches turns, only a partial flow, but not the entire flow, is obtained with a full one Winding-linked flux enclosed by a short-circuit winding. The one from the short-circuit winding enclosed partial flow collapses and is on the or the other return paths pushed away. The regular winding itself still wraps around the entire river, which does not change in size due to the diversion of the partial flow. Will the control contact moves on so that it only has a single head of the Regular winding touches, so the river displacement ceases, and all Conclusions are divided equally into the proportion of the total flow due to them. If the entire iron core is assembled from sheet iron in such a way that as possible there are few butt joints with the smallest possible air distances, and if so in particular Care is taken that this principle is used in the concatenation of the iron conclusions is guaranteed to each other, the electrical flow required for the Reversal of the partial flows in the inferences when switching through the control contact is required, very small, so that the spark formation at the control contact is very high is low. It is possible, as is known per se with multi-turn windings, to form the control contact from metallic material, which is a major advantage is. Because this material can withstand much higher loads than coal any overload, so it is short-circuit-proof and can be used without hesitation Oil are set, which provides better cooling of the transformer and thereby a Reducing its dimensions becomes possible. The formation of the sliding contact itself can be done according to different aspects depending on the expediency. One can perform it as one role, individually or in parallel with several. One can also use a sliding piece that is a brush of rotating electrical Machine resembles and how this is done in a brush holder, etc. The current dissipation or supply to the sliding contact can be done arbitrarily, z. B. via a flexible cable or via a contact slide that slides on a rail. For movement of the contact slide there are various options, e.g. B. Drive by spindles or chains etc.

Various types of construction can be selected for the control winding, e.g. B. Tubular coils with axially moving sliding contact or disc coils with radially moving Sliding contact. The circuit of the regulating transformer can be any, z. B. pure Economy circuit with or without excitation winding, circuit with separate windings per phase etc.

There is finally the option of the yoke leg, however at least one of these to be provided with a winding, each winding train connected in series to a switching capacitor, which is used to quench the spark serves.

This must be taken into account when dimensioning the iron backlinks take that their cross-sections are so large that they in the case of the river displacement do not affect the asymmetrical distribution of the flows in the inferences.

Depending on the tap on the control winding, the chaining of the winding parts or the switched-on part of the control winding with an excitation winding very much become unfavorable. One can effectively combat the stray flux by having a provides known thrust winding that z. B. with tubular design of the windings lies above the middle limb that carries the total flow.

The F i g. 1 to 5 illustrate embodiments and are intended to Explain the subject matter of the invention. The F i g. 1 a to 1 e show a single-phase Transformer with tubular winding and two iron backlinks in five consecutive ones Positions of the control contact. The F i g. 2 shows the side view of the same transformer on average. The F i g. 3 is intended to design a transformer with a disc winding illustrate. F i g. 4 represents a single-phase transformer with three iron yokes Fig. F i g. 5 explains the connection of a switched capacitor.

Let us first consider the transformer according to FIG. 1 to 2. The iron core consists of a middle leg 1 and the two magnetic yokes 2 and 3 (yoke leg). For the sake of simplicity, the sheets of 1, 2 and 3 are stacked on top of one another in the same planes, although there is no binding requirement for this. Since two iron backlinks have been chosen, the control winding must split up into two parallel-connected parts 4 and 5, which lie on the middle limb and are wound next to one another in the form of a tube, i.e. as a two-thread screw. In this exemplary embodiment, the two winding ends of the two partial windings are interconnected by the connections 6, 7 and 9, 10 and led to the discharge lines 8 and 11, respectively. This parallel connection does not necessarily have to be made at both winding ends (in the figures above and below). In some cases, interconnection at one end is sufficient. If the partial windings are connected in parallel at both ends, their total number of turns must of course be the same. This number of turns must be an integer; that is, it must encompass full turns, since otherwise the effect of the flow displacement would be disturbed. The leads 6, 7 or 9, 10 to the partial windings must be led one after the other through the spaces between the return legs. These spaces have a very simple shape in this exemplary embodiment. These are the spaces that are outside the iron body on both sides. According to FIG. 2 these are the following two spaces: a) to the right of the iron body and delimited to the left by its rightmost surface, b) to the left of the iron body and delimited to the right by its leftmost surface.

The bushings 6 and 9 are located in the space a, the bushings 7 and 10 in the space b.

The regulating contact 12 can be along the regulating winding (up or down) be guided. The standard winding is bare on this track; otherwise it becomes expedient isolated. The contact is made in such a way that the regular contact is either only one Only one conductor point touches or two neighboring conductor points, but never also the next but one managerial position. So at most it can be a short circuit between the partial windings, but not on a full turn of one and the same Partial winding take place.

The F i g. 1 a to 1 e represent five successive positions of the regulating contact. In FIG. 1 a, the regulating contact divides the assumed total of seven turns into five or two turns, respectively. Only the partial winding 4 is live. However, the immediately adjacent partial winding 5 absorbs a large part of the heat loss from partial winding 4 and dissipates it; so it is thermally not uninvolved. The river consists of parts 13 and 14. Both partial rivers flow together through the middle limb. Outside they are distributed symmetrically, that is, the partial flux 13 flows through the yoke 2 and the partial flux 14 the yoke 3. In FIG. 1 b, the control contact has moved a little further, it still touches the same winding point as before and also an adjacent winding point . The two partial windings are now connected, but with unequal numbers of turns. As a result, a short-circuit current can develop, which is indicated in the figure, specifically for the winding sections above the control contact with an arrow, and below with two arrows. The short-circuit current, which penetrates the plane of the drawing in the direction away from the viewer, is symbolized by a cross, and in the opposite direction by a point. In the lower winding sections, the symbols are correspondingly doubled. The following can be seen: In the left window of the sheet iron package, the ampere turns of the short-circuit currents cancel each other out, but not in the right. The latter is penetrated an odd number each by the upper and lower winding sections. The consequence of this is that the flow from the yoke 3 to the yoke 2 is displaced. In the middle column, however, the course of the river remains undisturbed. Only low energies are required to control the flow displacement, especially if care is taken to suppress air gaps in the iron backflows. The short-circuit current is therefore low and the generation of sparks when it is initiated or canceled is minimal. As a result, it is only possible to make the control contact from a metallic material. In addition, the control contact can be left in the bridged state for as long as desired without damage. The F i g. 1 c corresponds to a further movement of the control contact. It only stands on the one shown in FIG. 1 b added winding point which belongs to the partial winding 5. River displacement does not take place. The F i g. 1 d and 1 e show further positions of the control contact. They can be understood without further explanation. In Fig. 1 d, the flux is displaced after the other iron back yoke, namely from 2 to 3. In F .i g. 1 e is the control contact by a total of one turn compared to F i g. 1 a has been moved on. It now divides the control winding 4 into four or three turns.

The F i g. 3 shows as an example the implementation of the control winding as Disc winding. The numbers have the same meaning as before. The two partial windings 4 and 5 are wound as side-by-side, i.e. double-start spirals. At any point of the flat boundary surface of the disc winding can Regulating contact 12 can be moved back and forth.

In Fig. 4 are selected as an example three iron conclusions 2, 3 and 4 which are angled away from a common central column 1 sideways. The control winding is now divided into three parts 5, 6 and 7. The lower lead 8 and the upper lead 12 of the partial winding 5 penetrate the space between the iron backs 2 and 3. The leads 9 and 13 to the partial winding 6 penetrate the space between the iron backs 2 and 4. The leads 10 and 14 to the partial winding 7 pass through the space between the iron backs 3 and 4. The leads 8, 9 and 10 lead to the common line 11, analogously the leads 12, 13 and 14 to the line 15. For the sake of simplicity the movable control contact is not shown.

The F i g. 5 shows the connection of a switched capacitor. He should reduce the sparking that could occur when switching the control contact or suppress. Such sparking could result from overvoltages the change in flow upon initiation or termination of the displacement. This change in flux always takes place simultaneously in the iron backflows, namely in one inference in one sense, in the other in the opposite sense. Under In compliance with this law, the yoke legs can be provided with windings to which switching capacitors can be applied. You can do the winding switch each return leg to a separate capacitor or windings several return legs one behind the other on a capacitor. In the latter case z. B. is a winding on a yoke leg and is with the windings the other yoke leg in the opposite direction in series and onto the capacitor switched. Such winding trains and capacitors can then be used in the same number be provided as back yoke legs are available. In Fig. 5 are two Inference leg present. Each return leg 2 and 3 has a winding 15 and 16 provided. Both windings are in series in opposite directions switched and connected to the capacitor 17.

Only examples of single-phase transformers are shown. There are Of course, multi-phase combinations are also possible. Furthermore, there is only one at a time Winding, namely the regular winding, drawn. The regulating transformer can of course also wear other windings. The windings carried by the regulating transformer can be interconnected in any combination.

Claims (3)

Claims: 1. Regulating transformer with flux displacement, the m separate Has yoke leg and whose middle leg carries the control winding, of the voltage from turn to turn through a contact without interruption in such a way it is taken that this contact is at most m, preferably two adjacent turns touches, characterized in that the control winding in a known manner is designed as a multi-turn winding with m turns and that the flux displacement is achieved in the return legs that the leads to the partial windings outside the iron core in sequence through the spaces that follow one another are guided between the yoke legs and the partial windings through this Feeds can be switched directly in parallel. 2. Control transformer according to claim 1, characterized in that the central limb, which leads the entire river, is provided in a known manner with a thrust winding. 3. Regulating transformer according to claim 1 or 2, characterized in that at least one return leg, preferably all in appropriate Cascading, in are provided in a known manner with windings to which one or more capacitors are connected to the control contact to reduce spark formation. Into consideration Drawn pamphlets: German Patent Nos. 680 508, 682 537, 709 610, 756 855, 920 674; French patent specification No. 824 578.