DE102004012436A1 - Core sheet for inductive component - Google Patents

Abstract

The presented sheet metal section, consisting of an E-sheet (6) and an I-sheet (7), partially curved limited winding window (4, 5), the contour of which does not match the contour of the I-sheet (7). Nevertheless, the I-plate (7) during punching of the winding window (4, 5) won, which are produced in at least two punching steps. The outer contour of the magnetic circuit is essentially determined by the E-plate (6). This has at least in the region of its back portion corner radii and a cutout (19), which is also provided with rounded edges. The thus formed E / I-section is characterized by a uniform magnetic material utilization and even at high modulation by a low stray field. In addition, it has a very low construction volume and low weight for a given performance. Unnecessary material sections are removed in the stamping process and can be recycled. The E-plate (6) and the I-plate (7) can be separated from a metal strip both in the stamping process and in other separation processes.

Description

The The invention relates to a core sheet, as e.g. for the magnetic circuit of a series reactor or a transformer of a lamp or other equipment can be used.

The production of laminations, especially in EI-section has been the subject of optimization considerations for a relatively long time. For example, the DE 29 33 781 C2 an EI cut, where both the required E sheets and the required I sheets can be punched out of a single sheet metal strip. The punching process is essentially waste-free. The I-plates are created by the free-punching of the winding window in the metal strip, from which then the E-plates are separated. Only small polygonal cutouts produce waste. These cutouts are adapted at a position of the metal strip, in which a middle leg and two outer legs of the later E-plates abut each other. If necessary, the I-sheet can be configured with a rectangular trapezoidal shape. Further, it is possible to punch out I-plates whose length is less than the sum of the length of an outer leg and the middle leg.

The Use of high permeability sheets today allows the achievement of magnetic Inductions of significantly over 1.5 T in the magnetic circuit. Such materials, for example, up 1.7 T are controllable, but usually have a very pronounced saturation characteristic on. The characteristic curve can have a pronounced kink. At high Control of the magnetic circuit is therefore increasingly on it to avoid stray fields that otherwise cause losses and before everything to cause drunkenness could.

Of Furthermore, the aim is the relatively expensive high-permeability electrical sheet to use economically and on finished devices a To achieve high electrical performance with low weight.

From that It is an object of the invention, the sheet metal section known E-I sheets to improve.

This object is achieved with the EI-section according to claim 1:
The sheet metal section of the invention leaves conventional ways of thinking in which the shape of the I-sheet was determined by the shape of the winding window. In the case of the sheet metal section according to the invention, the shape of the I sheet deviates from the shape of the edge of the winding window. These shape deviations can be used to optimize the shape of the winding window, so that it is preferably rounded at both ends. This allows the accommodation of coilless windings with a high winding window filling level. Thus, the relevant, built up from the core sheets device can be reduced compared to devices with poorer filling level.

rounded Corners of the winding window avoid the formation of stray fields or weaken such stray fields considerably. Thus, the inventive E-I cut allows the construction of ballasts or transformers with low rumble tendency.

Preferably are the outer thighs longer as the middle thigh. The I-core sheet can thus between the outer leg of the E-core sheet. Its length is preferably lower as the sum of the length the inner thigh and the outer thigh. This makes it possible, relatively size Winding window for a given outer contour to achieve.

The outer leg shut down preferably with an arcuate transition section to the back section of the E sheet. The transition section preferably has a width that matches the width of the outer leg and the back section coincides.

The arc rounded corners of the winding window preferably have a radius on, which is bigger as five times the wire diameter of the wire from which a arranged in the winding window Winding is constructed. Preferably, the radius of curvature is greater than ten times the wire diameter. This will be particularly high filling ratios reached. The outer corner radius of the transitional section is preferably four times the rounding radius of the winding window. This results in a low-leakage structure of the E-sheet. The winding window is preferably generated in two consecutive punching steps. In the places at which the second punch contour adjoins the first punch contour are Recesses formed. These cause a tolerance compensation and avoid the formation of sharp edges or barbs on the edge of the winding window.

At the back portion of the E sheet, a preferably approximately triangular cutout is provided at a location aligned with the center leg. It thus creates a transitional section between the back portion and the middle leg. This is preferably formed symmetrically to the aforementioned transition section. Of the Cutout preferably has rounded edges whose radius of curvature coincides with the outer corner radius. This results in a uniform flow distribution in the E-sheet with low tendency to spill.

Of the Cutout preferably has a corner-free curved end on, which define a retaining lug on the piece of waste to be punched out. This facilitates the leadership the waste part in the punching tool.

The I sheet preferably has two arcuate edge portions delimiting the winding window on whose radius is larger than half the Width of the winding window. Thus, the winding window of the I-sheet arched completed, with the width of the I-plate and thus the width of for the magnetic flux available standing way is not significantly restricted. Without the inclination to increase the formation of a magnetic stray field is in this way generates a winding window shape, which has a high filling factor allows.

Further advantageous details of embodiments of the invention as well as the production of the E-I-section according to the invention can be found in the drawing, the description or claims.

In the drawing is an embodiment of the E-I-section illustrates. Show it:

1 an inductive component with a novel EI cut,

2 an E-plate and an I-plate of the magnetic circuit after 1 .

3 a section of the e-sheet after 2 on a different scale,

4 a section of the sectional contour of an E-sheet in the region of its winding window and an I-sheet,

5 to 7 the punching scheme of the E-plates and I-plates after 2 ,

In 1 is an inductive component 1 illustrated in the form of a series reactor or a transformer. The component 1 has a magnetic circuit 2 and a winding 3 on, for the two winding windows 4 . 5 are provided. The magnetic circuit 2 is made up of individual sheets that form an E / I cut. To him belong the in 2 illustrated E sheets 6 and I-plates 7 ,

The E sheets and the I sheets together form the magnetic circuit 2 whose winding window 4 . 5 rounded and the leg having a relatively constant width. The e-sheet 6 has two outer legs 8th . 9 and a middle thigh 11 on. The outer thighs 8th . 9 and the middle thigh 11 are over a back section 12 connected with each other. Between the outer thighs 8th . 9 and the spine portion are arcuate transition portions 13 . 14 arranged. These each have an outer corner radius Re, the width of the outer leg 8th respectively. 9 equivalent. The arc determined by the corner radius Re goes at its two ends in each case with a step 15 . 16 . 17 . 18 in the adjoining straight edge of the outer leg 8th . 9 or the back section 12 above.

The I-sheet 7 indicates an extension of the mean distance of the middle leg 11 width B ₂ to be measured. The outer thighs 8th . 9 each have a transverse to their longitudinal extent to be measured width B ₁ . The width B ₂ is greater, preferably significantly greater than the width B ₁ . This inevitably also the width of the winding window 4 . 5 to measure across the outer thighs 8th . 9 , significantly larger than the width B ₁ . B ₂ is less than the width of the middle leg 11 , The width of the middle leg 11 is preferably equal to the sum of the widths of the outer leg before 8th . 9 ie twice B ₁ .

The magnetic circuit is characterized in that each cross section measured perpendicular to the respective magnetic flux direction is approximately the same size. Exceptions exist only in the area of the I-sheet 7 , So-called cutting edge losses (which are increased core losses resulting from material deformation in the vicinity of the punched edges) are reduced by the small available cut edge lengths and by the largely homogeneous magnetic field formation. In particular, the E-plate of the magnetic circuit has no non-functional areas. Rather, the magnetic flux is distributed relatively uniformly over the entire E-plate.

The back section 12 is in alignment with its middle leg 11 on the side facing away from this with a section 19 provided in 3 is shown separately enlarged. The cutout 19 is approximately triangular and connects to the straight edges of the back section 12 with steps 21 . 22 at. Starting from these, rounded edges extend 23 . 24 to a degree 25 on which the edges 23 . 24 connect corner-free to each other. The conclusion 25 is formed by an opening in the form of a pointed arch or a round arch, whose legs are S-shaped to the edges 23 . 24 connect. The edges 23 . 24 have a radius of curvature R which coincides with the corner radius Re matches.

The profile of the winding window 4 respectively. 5 turns out 4 , Its edge 26 is through two overlapping cuts 27 . 28 each determining a part of the edge contour. The cut 27 In its outline corresponds to the shape of the I-plate 7 , The cut 28 joins the cut 27 and concerns the back section 12 facing end of the winding window 4 respectively. 5 , The cut 28 is at both ends 31 . 32 where he is at the cut 27 joins, led in a bulge outward, in the edge 26 forms a recess. The bulge 31 then go back to a straight section 33 above. In the transition to the back section, he is again guided slightly outward and with a radius of curvature 34 rounded. This is significantly larger than the wire diameter of the winding 3 used wire. Preferably, it is about one quarter of the corner radius Re. Likewise, a rounding radius 35 formed on the opposite corner.

The cut 27 , the contour of the I-sheet 7 determines has at its end on one side an arcuate curved section 36 whose length corresponds approximately to the width of the winding window and whose radius of curvature Rk is greater than the width of the cut 27 , This shows the I-plate 7 , like out 2 it can be seen on which the winding window 4 or 5 covering area, a curved edge on. Between both curved sections 36 is a straight section 37 provided, the width of the width of the middle leg 11 corresponds and thus can lie flat against this.

For completeness, it should be noted that the outer leg 8th . 9 on its outside near its free end with recesses 38 . 39 are provided, the attachment of the magnetic circuit 2 on a support plate or the attachment of a retaining clip for the I-plate 7 serve.

The production of the E-sheet 6 and I-sheet 7 is described below on the basis of the punching scheme according to 5 to 7 described:
The production of E sheets 6 and I-plates 7 goes from one to 5 dashed lines shown metal strip 41 out. The E sheets to be produced 6 and I-plates 7 are shown in dashed lines. This metal strip 41 is guided with a step size through a punch, the outer distance of the outer leg 8th . 9 equivalent. The increment is in 5 denoted by S and indicated schematically. In a first punching step, four cuts are made 27 attached so that the corresponding I-plates in the same orientation, ie with their sections 36 For example, without exception, pointing to the right or to the left are made. This punching step is in 5 denoted by A.

In a subsequent punching step B, which is offset by an increment S or an integral multiple thereof, the cuts are made 28 appropriate. This serves to complete the contour of the winding window 4 . 5 ,

In a next punching stage C, the cutouts will be 19 produced as well as the still to be produced middle leg 11 in a free cut of their opposite still to be produced outer thighs 8th . 9 separated. In addition, at the later back sections 12 a cut be made that the cutout 19 at the outer edge of the sheet sets. This part of level C is still in 6 illustrated. In a further step D, cuts will be made 49 attached to make the corner radii Re. In addition, the recesses 38 . 39 optional. This produces all non-linear contours. In final punching steps E, F (see also 7 ) become the E sheets 6 sporadically.

In all punching steps are those to be removed by the punching step surfaces hatched illustrates.

The in 1 illustrated magnetic circuit 2 is particularly suitable for the production of windingless inductive components. The curvilinear winding window 4 . 5 whose outline in particular in the area of the back section 12 is formed corner-free, allows the accommodation of a bobbin coil. Such is formed for example by a wire coil, which is surrounded only by insulating film. The presented magnetic circuit 2 is also magnetically optimized. He has an extremely low stray field even if it is made of high permeability material with kink line and operated with high modulation.

The presented sheet metal section, consisting of an E-sheet 6 and an I-sheet 7 , Partially has arcuate winding windows 4 . 5 whose contour does not match the contour of the I-plate 7 matches. Nevertheless, the I-sheet is 7 when punching the winding window 4 . 5 obtained, which are produced in at least two punching steps. The outer contour of the magnetic circuit is essentially through the E-plate 6 established. This has at least in the region of his back section 12 Corner radii and a section 19 on, which also has rounded edges 23 . 24 is provided. The thus formed E / I-section is characterized by a uniform magnetic material utilization and even at high modulation by a low stray field. In addition, it has a very ge small volume and low weight for a given performance. Unused material sections are removed in the stamping process and can recy be celt. The e-sheet 6 and the I-sheet 7 can be separated from a sheet metal strip both in the stamping process and in other separation processes.

Claims (19)

Core sheet, in particular for the magnetic circuit ( 2 ) a ballast or a transformer of a lamp, with an e-sheet ( 6 ), which has a middle leg ( 11 ) and two outer legs ( 8th . 9 ), which between each other a winding window ( 4 . 5 ), with an I-plate ( 7 ) for closing the magnetic circuit between the outer legs ( 8th . 9 ) and the middle leg ( 11 ), characterized in that the shape of the I-plate ( 7 ) of the shape of the winding window ( 4 . 5 ) deviates. Core sheet according to claim 1, characterized in that the outer limbs ( 8th . 9 ) are longer than the middle leg ( 11 ). Core sheet according to claim 1, characterized in that the sum of the length of the inner leg ( 11 ) and the length of the outer leg ( 8th . 9 ) is greater than the length of the I-plate ( 7 ). Core sheet according to claim 1, characterized in that the outer leg ( 8th . 9 ) with an arcuate transition section ( 13 . 14 ) to a back portion ( 12 ) of the E-sheet ( 6 ) adjoins. Core sheet according to claim 1, characterized in that the winding window ( 4 . 5 ) has arcuately rounded corners. Core sheet according to claim 1, characterized in that the corners have a radius of curvature ( 34 . 35 ), which is greater than five times the wire diameter of the wire from which a winding to be arranged in the winding window (FIG. 3 ) is constructed. Core sheet according to claim 4 and 6, characterized in that the transition section ( 31 . 32 ) has an outer corner radius (Re), Core sheet according to claim 7, characterized in that the outer corner radius (Re) is three to five times, preferably four times, the radius of curvature '( 34 . 35 ) having. Core sheet according to claim 1, characterized in that the winding window ( 4 . 5 ) is produced in at least two punching steps, wherein a part ( 27 ) of the edge ( 26 ) of the winding window ( 4 . 5 ) in a first punching step and another part ( 28 ) has been produced in a second punching step. Core sheet according to claim 9, characterized in that in the transition of the parts ( 27 . 28 ) of the edge ( 26 ) Recesses ( 31 . 32 ) are formed. Core sheet according to claim 1, characterized in that the E sheet has a back portion ( 12 ), which at one with the middle leg ( 11 ) aligned position with a cutout ( 19 ) is provided. Core sheet according to claim 11, characterized in that the cutout ( 19 ) is substantially triangular. Core sheet according to claim 11, characterized in that the cutout ( 19 ) rounded edges ( 23 . 24 ) having. Core sheet according to claim 7 and 13, characterized in that the rounded edges ( 23 . 24 ) have a radius of curvature (R) that coincides with the outer corner radius (Re). Core sheet according to claim 11, characterized in that the cutout ( 19 ) at its the middle thigh ( 11 ) end facing a cornerless arched completion ( 25 ) having. Core sheet according to claim 1, characterized in that the I-sheet ( 7 ) two the winding window ( 4 . 5 ) bounding arcuate edge portions ( 36 ) having. Core sheet according to claim 16, characterized in that the arcuate edge portion ( 36 ) substantially over the entire width of the winding window ( 4 . 5 ). Core sheet according to claim 16, characterized in that the radius (Rk) of the edge portion ( 36 ) is greater than half the width of the winding window ( 4 . 5 ). Core sheet according to claim 1, characterized in that the width (B ₂ ) of the I-sheet ( 7 ) is greater than the width (B ₁ ) of the outer leg ( 8th . 9 ) of the E-sheet ( 6 ).