DE2521666A1 - STAR-SHAPED CORE ELEMENT FOR MAGNETIC FLOW FORMATION, PROCESS FOR ITS MANUFACTURING AND TRANSFORMER MANUFACTURED FROM IT - Google Patents

Description

Dipl. Ing.PetOT Otto 2521 666 ⁷ STUTTGART 8O (Valhlngen)

Patent attorney Waldburg Strasse 48

Tetphone (0711) 734627

1148 / ot / EO
May 12, 1975

Establishments Martin et Cie.

8o, Rue Fondary

75o15-Paris / France

Star-shaped core element for the formation of magnetic flux, process for its manufacture and transformer made from it

The invention relates to a star-shaped core element for forming a magnetic circuit, in particular are suitable for use in multi-phase transformers.

Multi-phase transformers, especially three-phase transformers or three-phase transformers are known in the classic way in that they are either of the Ε-type, i.e. they have three cores in one level or they have five cores in one level, plus there are still the jacketed type. If one refers in this context to classical theoretical work on multiphase transformation

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ntators. (See in particular the article "Cauxs de Machines Electriques", CJ.Ä.M. by M. Beliier or "Electrotecimique generale". Editions Scientifiques Rifoer, Volume 3 _r by Ä. Bussen) _t then it can be stated that these three Transforraatorarten have the kachteil _r that they have an asymmetrical magnetic circuit because the length of the yoke to be traversed by the magnetic flux is not the same when going from one outer core to the middle core or to the other outer core. Various means have been tried been to this imbalance too. _t nichts_destoUfcrotz encounter, however, the magnetic circuit in these arrangements is unbalanced, so that the determination is readily applicable and that the primary load currents for the three phases are different, yet different the services required of these phases. In the same classic theoretical work on polyphase transformers mentioned above, there is practically always a short introductory section in which it is stated that the arrangement of a transformer in a star shape would be the ideal shape for a symmetrical three-phase transformer or three-phase transformer, but that this is why it is such a shape cannot be used because this would lead to air gaps in the central region of the star-shaped magnetic flux circuit, namely to such gaps which would be very difficult to close under pressure, so that this would lead to considerable losses in the magnetic circuit.

The present invention is therefore based on the object of creating a star-shaped core element which is located in the center of the star Ipunktsbereich has no joints or gaps. This then includes the creation of a manufacturing

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Method for such a star-shaped core element forming elements and the information on how the inventive star-shaped core element can be used to form a magnetic circuit in a multi-phase transformer. Finally, the present invention succeeds in creating such a multi-phase transformer in which the Assembly of the electrical windings can be done in a simple form.

To solve this problem, the invention is based on the star-shaped core element mentioned at the beginning and consists according to the invention in that the two adjoining half-limbs belonging to two neighboring limbs of the star formed from a single piece of magnetic material or from a layering of such pieces in are composed in such a way that in the magnetic current flow from one half-limb to the adjacent half-limb there is no magnetic reluctance gap and that each leg of the star is so formed is that it can accommodate one or more electrical windings.

The invention thus provides a star-shaped core element available, in which the at least two adjoining half-limbs of two adjacent limbs of the star-forming material continues in the sense of the magnetic flux lines.

One method of manufacturing such a star-shaped core element is that of forming a toroidal one magnetic circuit a magnetic sheet strip is wound and that with the help of an action on n, in regular Points distributed at angular distances by means of a

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Pressure device, the core element having a toroidal shape is deformed and that the deforming action so is carried out for a long time until the two half limbs of each star limb are joined together over most of their length are.

A star-shaped core element according to the invention can be therefore win by first producing a toroidal core or torus for the magnetic path by a magnetic sheet is wound up in a corresponding manner; then this toroid is then through again a pressure device that acts on several points distributed over the circumference of the torus at regular intervals, converging or merging deformed in such a way that a star shape results. This "star shape" can also can also be produced by assembling magnet elements bent in a V-shape, each V-shape then forms two adjacent half-legs of adjacent legs. Finally, the star shape also produce that magnetic rod shapes, each forming a leg, at their central merged ends are clamped between two flanges made of magnetic material, so that too in this way the formation of gaps in previous systems is avoided. Each leg of the star has an overall configuration on, which is designed so that it allows the inclusion of one or more electrical windings.

In addition, the present invention relates to the use of such a star-shaped core element as part a polyphase transformer or as part of a phase change transformer. This is the aim of the invention from a multi-phase transformer using

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formation of a star-shaped core element according to one or more of claims 1 to 9 and according to the invention consists in that on each leg of the star-shaped core element electrical Windings are arranged and that on a surface of the core element, a magnetic path element in the form of a Yoke is arranged, the dimensions of the yoke substantially equal to twice the length of the star legs are, the yoke rests on the star and clamping elements are provided to the yoke with the star-shaped core element to squeeze.

Therefore coils are arranged around each leg of the star-shaped core element, the magnetic circuit is then made by toroidal ones Return rings or yokes, which are arranged on both sides of the star-shaped core element, closed, The radius of the yokes running towards the outer circumference is essentially the same as the leg length of the star-shaped one Core element; the yokes are pressed against the core element and clamped to them by suitable clamping and pressing means. The invention therefore succeeds in creating an electrical transformer in which a perfect symmetry the phases is realized; In the case of this transformer, the ones that have already been pre-wound are particularly simple To assemble coils, which are simply applied to each leg of the star-shaped core element, then the toroidal yokes are placed on the legs and clamped and pressed together in a simple manner. In terms of their mass and volume, such transformers have considerable advantages over classic, a Ε-shape, five webs or a jacketed shape having three-phase transformers, since they are the same Power can be made smaller and lighter and require significantly less iron and copper. About that

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In addition, due to the lack of the longitudinal gap in the star, the efficiency, the no-load current, as already mentioned, are the Weights for the iron and copper used are reduced, in each case compared to a conventional transformer the same Power.

Further embodiments of the invention are the subject of Subclaims and laid down in these.

In the following, embodiments of the invention, methods for producing core elements according to the invention, a Device-based training for carrying out the method and transformers made from the core elements explained in more detail with reference to the figures according to structure and mode of operation. Show:

Fig. 1 and 2 in a schematic representation of an inventive Method for the production of magnetic core elements in the form of a star according to a first embodiment ,

Fig. 3 shows a second possibility for forming a star-shaped Core element for a transformer that

FIGS. 4a and 4b each show, in a top view and in a side view, a third exemplary embodiment for formation of star bodies according to the invention for the magnetic flux,

Fig. 5 shows a fourth embodiment for the production of magnetic flux bodies in the form of a star,

Fig. 6 serves to explain a manufacturing method for

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Formation of a V-shaped element as part of a star-shaped core element according to the invention, for example for use in Fig. 5,

FIG. 7 shows an example of an annealing process for the V-shaped elements produced according to FIG. 6 and for the

8a and 8b show the top view and the side view of a three-phase transformer according to the invention represent.

In the following, the expressions "star connection" or simply "star" are used to denote a magnetic circuit or a magnetic flux path in the form of a star, in short a star shape. In addition, it should be noted that in the following DESCRIPTION OF EXEMPLARY EMBODIMENTS Reference is essentially made to three-leg star-shaped systems. However, it is obvious to those skilled in the art that such star shape systems or magnetic flux path systems can be used in Star shape can include any number of legs, which are designed so that to realize the present Invention other multiphase currents and not exclusively three-phase currents can be included.

In the embodiment of FIG. 1, a toric element for forming a magnetic flux path is shown which is arranged between three press jaws 2. The toric element 1 itself is preferably made in that a Strip of a magnetic sheet has been wound on a spindle. The manufacture of such toric elements leaves can be carried out without difficulty in companies that deal with the production of magnetic core shapes, too are such machines for the production of toroidal winding cores

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well known; This is also why the preferred Use of such toric elements is indicated in the following description, although basically also other, original forms of embodiment for the element 1 can be provided, for example polygonal arrangements. The three Press jaws 2 are part of a pressure or molding device which is designed so that forces on the press jaws in can be exercised in such a way that they can be brought together to point 1.

In Fig. 2 is the final step of the manufacturing process shown; the jaws 2 are already easily solved. From the illustration of FIG. 2 it can be seen that the element 1 has assumed the shape of a star due to the pressing process, a shape that is practically complementary to the shape the pressing jaw runs, with a central free space being provided in the star, in particular in the present case, which is below Circumstances of the introduction of a fastener can be used. The presence and shape of this space can be determined by the shape of the press jaws; In addition, a molded piece of the given training can also be used before the pressing process can be entered at the center of the toric element 1 to determine the final shape of the space.

Once you have achieved the star shape shown in Fig. 2, then other customary machining operations can also be carried out on these elements that form closed magnetic circuits perform, in particular, the star system produced can be subjected to a thermal treatment, too the system can be subjected to conventional impregnation processes, for example an impregnation bath or an impregnation in a vacuum will. Finally, it is also possible to carry out a surface treatment or grinding process after the impregnation

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to be carried out on specified areas of the star surfaces.

In Fig. 3, a star system 1o is now shown, which consists of three layers, stacks or packages 11, 12 and 13 of pre-cut and pre-folded magnetic sheets, which each form three adjoining half-legs of the star. Each pair of adjoining half-legs 11, 12 and 13 can be manufactured and molded either starting from a stack of flat magnetic sheets which are then folded or from a stack or a layering of pre-folded magnetic sheets. It should be noted that the illustration of FIG. 3 represents the basic principle essentially only indicates schematically and that in fact the end regions of the legs of the star are not are aligned, but due to the fold or bend and the stacking, become a slight Longitudinal displacement between the respective ends of each sheet, which together form the stack, results.

The various legs of the star can then be connected to one another by any means, including known means be, for example with heat-shrinking jackets or sheaths, with the help of clamps or through the connection with rivets arranged in openings. It should be noted that the star system 1o of FIG represents a simpler construction than the star 1 in Fig. 2, and is then suitable when cases arise at to whom the dimensions of the star are of great importance. However, this benefit has to be paid for by necessity are to provide additional mechanical means to ensure the mechanical cohesion of the star.

4a and 4b is once in side view and once

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in plan view a third embodiment of an inventive-'gem Star system shown. The star shown there consists of three legs 21, 22 and 23; the unity the magnetic path in the center of the star is ensured by two flanges or side plates 24 and 25, through which a central opening is drilled which press-fit the flanges with and against the inner central ones Areas of the star leg made possible, for example with the help of bolts and screws, so that on the one hand the mechanical cohesion and on the other hand the closeness of the magnetic path is ensured. The central type of attachment can also be replaced by lateral fastening options. The one having a central opening Flanges advantageously consist of rolled or wound magnetic strips or sheets. Each of the thighs 21, 22 and 23 can either consist of a stack of magnetic sheets, which by any mechanical means in known Held together in a heat-shrinkable manner or sheaths, clamps, rivets), on the other hand, each of the legs 21, 22 and 23 can also proceed from a toric, so circular magnetic path winding are produced, which are pressed together between two flat surfaces is. With this latter solution, it is not necessary to use mechanical connecting means for the respective Provide laminated core, which forms each leg of the star.

In Fig. 5, a magnetic flux path 3o is shown in a star shape, formed from three identical V-shaped elements 31. Each of the V-shaped elements is made by that it is assumed that a toric magnetic core is made in any known manner from a magnetic sheet

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is made by winding, and which is then flattened and shaped in such a way that it is the in Fig. 5 assumes shown V-shape.

The simplest manufacturing process for such a V-shaped Element is that in a press to produce a flattened bar shape without a central Slot opening a magnetic core torus is flattened. The bar shape is then bent by known means. However, this very simple manufacturing process has a slight disadvantage, which is that, as can be seen from an examination of one of the V-shaped elements, the sheet metal length in the concave area of the element is shorter than the sheet metal length in the convex part of the element. Therefore, in the course of the bending process, a Sliding of the individual sheet metal layers on top of one another, this sliding, however, due to the strong curvature at their ends having flattened zones of the rod shape is made more difficult. This may result in deformations and deformations, even cracks in the sheets. This manufacturing process is therefore only advisable for very elementary magnet shapes and magnetic flux areas or for such magnetic cores, which are formed from a very small number of windings.

In Fig. 6 is a preferred embodiment method for obtaining such V-shaped elements according to the present invention shown. Around the magnetic sheets in the course of their forming process their relative sliding on each other without excessive tension (Elongation or compression) that modify the formed length or its crystalline structure would impair in a way that could no longer be repaired,

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it is necessary to start with the shaping of the knee-shaped bent areas with strong radii of curvature at the ends to distance itself from the bar shape. Therefore, in FIG. 6

4o
the reference number denotes a die in the form of a V and the reference number 41 denotes a central punch or ram; the reference numeral 42 then designates a second stamp surrounding the first stamp. Both stamps can be operated on each other in an independent manner. The shape of the magnetic core torus before the action of the stamp is provided with the reference number 43 and the already deformed shape of the magnetic core torus in the course of the manufacturing process after the action of the first punch is provided with the reference number 44 in FIG.

According to a feature of the invention, these Manufacturing process then proceeded so that the undeformed Torus 43 made of magnetic sheets is initially inserted into the die 4o and the central punch 41, which is the inner Area of the V is opposite, is brought into action; in this way the torus then assumes the shape indicated by the reference numeral 44. Then the second enveloping punch 42, which essentially develops a complementary counter-shape to the die 4o, for action brought and enables the production of a V-shaped element corresponding to the element 31 of FIG. 5. It understands This manufacturing process just described is subject to numerous changes and modifications can be, in particular a combined or differential mode of operation of the central punch and the enveloping stamp should be considered. It is also possible to use intermediate punches, one at a time and one after the other have larger dimensions.

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In order to facilitate the sliding of the individual sheets on one another in the course of the deformation process, during the Manufacture of the original magnetic magnetic core torus 43 introduced a lubricant between each individual winding will. This lubricant can be, for example, fat, oil, sebum, talc or something else act with a suitable lubricant. Otherwise, there is between the contact area of the toroidal element to be deformed 44 in the course of the molding process and the enveloping punch 42 a sliding process. This sliding can thereby be facilitated that one in the contact area of the punch 22 ball or roller bearings or other known Arrange lubricants or lubricants.

FIG. 7 shows a preferred exemplary embodiment for the thermal treatment of the V-shaped elements 31 in the present case Invention. These elements 31 are in an annealing furnace 5o between two punches, a concave punch 51 and a convex punch 52 is inserted so that a pressing or pressure effect can take place. The stamp or print elements are moved in the direction of the arrows shown, so that the introduction and removal of the V-shaped elements according to the respective annealing or soft annealing can be carried out at each furnace end. It is appropriate in this context known technical processes possible, both the loading and the removal automatically as well as the Advance the V-shaped elements 31 step by step; in this way it is ensured that a thermal Treatment of predetermined duration is achieved. In addition, it is of course also possible to switch between each of the V-shaped magnetic elements to arrange spacers or spacers of the same shape, for example each between the second, third, fourth and the following magnetic

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see element can be arranged.

FIGS. 3a and 8b each show embodiments of a three-phase or three-phase transformer in side and front views shown, which verv / ends a star-shaped magnetic core according to the invention for the magnetic flux. In the representations of FIGS. 8a and 8b, there is a star-shaped magnetic core according to the exemplary embodiment in FIG used; it goes without saying, however, that any other star shape described here can also be used. The one shown Three-phase transformer has 4 windings, which are arranged on each star leg, then are yokes or return rings 5 attached to both sides of the star in order to close the magnetic path. The contact- or the area of contact between each yoke 5 and the star is greater than or equal to half the cross-sectional area of one Star leg. In this way, the reluctance or magnetic resistance is at the connection areas of the yokes or, more precisely, the gap area is considerably reduced. Such a transformer can comprise simple tensioning means; due to the fact that the gap surface between the yokes and the star is large, there is no need for surface finishing or grinding to be carried out at the contact areas. None the less, can do less of course, if this is considered to be desirable for particular purposes, such a surface treatment or a grinding process can be carried out. The assignment of the star 1 to the two toric yokes 5 forms an extremely robust and non-deformable mechanical unit, with the outer gaps or connecting areas can derive maximum benefit directly from the action of the clamping device, as this leads directly to tightening which leads to connection areas. Such a training one

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three-phase transformer or three-phase transformer has the significant advantage that the length of the flux lines and the overall dimensions are considerably reduced with respect to other transformers of the same power. It also has a given power due to the lack of connection areas or gaps in the center of the star such a device according to the invention has a better efficiency, a lower no-load current lower iron weight and lower copper weight; this latter characteristic is essentially due to the fact attributed to a very effective clamping or densification of the crevices; it is therefore possible with very high To work induction in a magnetic circuit, for example with 1.8 to 2, ο Tesla and thus also the current density in to increase the coils. The tapered windings of these coils allow the transformer to be small in size are held, in addition, it can be stated that the transformer described in FIGS. 8a and 3b still has the advantage of good ventilation due to the large dimensions of the windows.

The person skilled in the art is aware that the explanation given with reference to FIGS. 3a and 3b is exclusively a special one Represents an application example of a star according to the invention; it goes without saying that such an element is for one magnetic circuit can also be used / ends in numerous other application examples, for example in a six-phase power transformer, using a star with six legs or a four-phase Power transformer using a four-legged star. It is also possible this way to provide transformers that change the number of phases, i.e. transformers that convert a three-phase current into a six-

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convert phase current or two-phase current to three-phase current, etc. In a similar way, a transformer according to the invention can be used for measuring and regulating the balance of the currents in a multiphase network. The yokes 5 for the return paths have been described above in such a way that they comprise a toric shape; it goes without saying, however, that these yokes can also have any other polygonal shape in order to
to meet special requirements.

In the foregoing, the entirety of the magnetic circuit in star shape, of yokes and associated windings been regarded as a transformer, but it is understood that depending on the structure and nature of the windings and the electrical connections this set represent a multi-phase transformer or a multi-phase coil circuit can.

In the present embodiment, the star shape is in
to understand the broadest sense; it goes without saying that the star need not necessarily be regular. In addition, as usual, the present invention is not restricted by the exemplary embodiments shown, but rather encompassed
also the usual configurations and modifications within the scope of the invention.

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Claims (1)

May 12, 1975 - / - PATENT CLAIMS: 1. ^ star-shaped core element to form a magnetic ^ - ' circle, characterized in that the two adjacent and to two adjacent legs of the star (3o) belonging half-legs are formed from a single piece of magnetic material or from a layering of such pieces in the Are composed so that in the magnetic current flow from one half-limb to the adjacent half-limb there is no gap forming a magnetic resistance and that each limb of the star (3o) is designed so that it can accommodate one or more electrical windings (4). 2. Core element according to claim 1, characterized in that the material of the star so formed is a single strip of a magnetic sheet is. 3. Core element according to claim 1, characterized in that it consists of a layering of magnetic sheets bent into a V-shape is formed in such a way that each layer (11, 12,13) forms two adjacent half-legs of the star (1o) and that the magnetic sheets making up each leg are interconnected by suitable mechanical connecting elements. 4. Core element according to claim 3, characterized in that each adjacent half-limb of the star forming magnetic sheet layers (11, 12, 13) made of pre-cut 509849/0687 1148 / ot / EO OCOICCO May 12, 1975: Ιθ / \ ΟΌΟ -Sf- ten flat and arranged in package form and then bent sheets. 5. Core element according to claim 3, characterized in that each layer (11,12,13) consists of pre-cut and pre-bent and then consists of sheets assembled to form a laminated core. 6. Core element according to claim 1, characterized in that the star (1o, 2o, 3o) consists of a number of pairs of contiguous Half-limb in V-shape, each half-limb pair (31) made of a wound magnetic sheet existing torus is shaped. 7. Star-shaped core element for forming a magnetic circuit, characterized in that formed separately and one or more legs (21, 22, 23) receiving electrical windings are provided and in their region of convergence are held and connected by the pressure between two flanges (25) made of magnetic material. 8. Core element according to claim 7, characterized in that each leg (21,22,23) of the star (2o) consists of a layering consists of flat magnetic sheets that are connected by suitable mechanical means. 9. Core element according to claim 7, characterized in that each star leg (21,22,23) is made by that a toroidal shape made of wound magnetic sheet is pressed between two flat surfaces. 1o. A method for producing a star-shaped core element according to one or more of claims 1 to 9, wherein for 509849/0687 1148 / ot / EO £ 3 zl May 12, 1975 Forming a toric magnetic circuit, a strip of magnetic sheet is wound up, characterized in that that by convergent, i.e. converging, action on n, points distributed at regular angular intervals by means of a pressure device the core element having a toric shape is deformed and that the deforming Action is carried out until the two half limbs of each star limb over the largest Part of their length are joined together. 11. The method according to claim 1o, characterized in that each sub-element (2) of the printing device is essentially one has the complement of the desired shape between two star legs corresponding shape, such that no further shaping treatment is required after the printing / pressing process. 12. The method according to claim 1o or 11, characterized in that that the core element (1) obtained in this way is thermally treated, subjected to an impregnation process and at predetermined Surfaces of the star shape are surface treated or abraded. 13. The method according to one or more of claims 1o to 12, characterized in that the pressure device consists of three pressing jaws (2) offset by 12o to form a « star-shaped core element (1) with three legs. 14. Method for producing a V-shaped element according to Claim 6 for the formation of a star-shaped core element, characterized in that a torus shape is produced by winding a magnetic sheet and the torus compressed to form a straight bar shape 509849/0687 1148 / ot / EO
May 12, 1975 and that the rod shape thus formed is bent into a V-shape. 15. Method for producing a V-shaped element according to Claim 6 for the formation of a star-shaped core element, characterized in that a torus made of magnetic Wrapped sheet metal and the torus is inserted into a die having the required angle of a V-shape and that the torus (43) is pressed against the die (4o) by punches (41, 42) which are becoming larger in size will. 16. The method according to claim 14 or 15, characterized in that that during the manufacture of the torus wound from magnetic sheet the magnetic sheets prior to the winding process with a Lubricants are provided. 17. The method according to claim 15 or 16, characterized in that that the torus compressing the stamp (41,42) on their contact surfaces with the torus with sliding and / or Lubricants are provided. 18. The method according to one or more of claims 14 to 17, characterized in that the V-shaped elements (31) obtained in this way are annealed in a furnace, with them under Compression pressure are arranged placed against each other to avoid deformation. 19. The method according to claim 18, characterized in that the annealing furnace has a device for automatic and sequential loading and for automatic and having consecutive discharge. 509849/0687 1148 / ot / EO OR? I. May 12, 1975 * ^OZ ' 20. From the core element according to one or more of the claims 1 to 9 manufactured polyphase transformer, characterized in that on each leg of the star-shaped Core element electrical windings (4) are arranged and that on a surface of the core element a magnetic Path element in the form of a yoke (5) is arranged, the dimensions of the yoke being substantially equal to the are double the length of the star legs, the yoke rests on the star and clamping elements are provided around the Pressing the yoke together with the star-shaped core element. 21. Transformer according to claim 2o, characterized in that on the second surface of the star-shaped core element a further yoke (5) and the three elements forming the magnetic path by suitable clamping arrangements are clamped or compressed. 22. Transformer according to claim 2o or 21, characterized in that that the contact surface between one of the legs of the star-shaped core element (1) and the or the yoke (s) (5) is larger than the cross-section of the leg. 23. Transformer according to one or more of claims 2o to 22, characterized in that the magnetic yoke element has a toroidal shape in the form of a yoke (5). 509849/0687