FI71210C - FREQUENCY REARING FOR E-FORMED CARBON PLATERS AND I-FORMED SLIDING PLATES I AND THROTTLE ELLER TRANSFORMATOR SPECIFICALLY FOR GASURLADDNINGSLAMPOR - Google Patents

Description

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(51) Kv.lk.7int.CI. * H 01 F ** 1/02 // H 01 F 3/02, 27/2 ** g Q j__ pj ^ Q (21) Patent application - Patentansökning 8026 * 48 ( 22) Date of application - Ansökningsdag 21.03.80 (Fl) (23) Starting date - Giltighetsdag 21.08.80 (41) Has become public - Blivit offentlig 22.02.8 1

National Board of Patents and Registration / 44) Date of display and publication. - 1 * 4.08.86

Patent and registration authorities '' Ansökan utlagd och utl.skriften publicerad (86) Kv. application - Int. ansökan (32) (33) (31) Privilege claimed — Begärd priority ^ ^ .08.79

Federal Republic of Germany-Förbundsrepubli ken

Germany (DE) P 2933781.3 Proven-Styrkt (71) Hermann Schwabe, Wasenstrasse 25, 7067 Urbach / Wiirtt.,

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (72) Bernhard Albeck, Waiblingen-Neustadt, German-Federal Republic-Förbundsrepubl iken Tyskland (DE) (7 * 4) Oy Koi s te r Ab (5 * 4) Method of choke or transformer E-shaped for the manufacture of cores and L-shaped shut-off plates, in particular for gas-discharge lamps -Förfarande för framstä11 Ning e E-formiga cores and L-formiga slutplates i en choke or transformer specially for gasur1addningslampor

The invention relates to a method for manufacturing I-shaped baffles between the E-shaped core plates of a choke or transformer and their arms, in particular for use as a pre-switching device for gas discharge lamps, the outer arms of the E-shaped core plates possibly being provided with notches around a clamping rail.

In connection with the production of E-shaped core plates and I-shaped closure plates according to DIN 41300 (page 2) without material loss, a stamping method is already known in which the arms of two E-shaped core plates are turned opposite to each other so that two I-shaped closure plates are punched . Although this plate part can be made without Stans dry waste, the disadvantage in this case is that the size of the air gap between the middle arm of the E-shaped core plates and the I-shaped closing plates is determined by the stamping tool. Thus, the size of the air gap 2,71210 cannot be adjusted to the desired value to eliminate manufacturing tolerances. Therefore, with this stamping method, it is also not possible to manufacture an air gap belonging to the desired impedance so that the winding space could be fully utilized. However, even if several different and expensive stamping tools were used, only rough adjustment would be achieved. In addition, stamping the air gap required for each coil causes additional work, which in turn unreasonably increases labor costs. Admittedly, it would be possible to arrange air gaps between the ends of the E-shaped core plate and the ends of the I-shaped closure plate. However, this increases the installation cost of the E- and I-lamellae, and due to the external air gap, a magnetic stray flow is also created, which can cause annoying noise.

AT-PS 294 270 further discloses a sheath core plate structure made of E-shaped core plates and I-shaped closure plates such that i-shaped closure plates are inserted between the shank portions of the E-shaped core plates. The aim of this structure is that the jacket core can be surrounded by a housing jacket and a base, regardless of the shape of the lamellae, so that no magnetic stray flow is generated and so that the lamellae are pressed firmly together.

With the present invention, the method of manufacturing the lamellae is again aimed at such that the E-shaped core plate and the I-shaped barrier plate can be stamped either completely without material loss or at least very small, and in addition the magnetic circuit lamellas can be arranged so that the air gap can be adjusted. according to need.

According to the invention, this is achieved by stamping two rows of E-shaped core plates with their open sides facing each other and half offset from each other by their length relative to the central axis so that the end of each outer arm of two adjacent E-shaped core plates contacts the opposite, displaced E-shaped core plate. at the end and from the free spaces created between the outer arms and the middle arms of the opposite E-shaped core plates, I-shaped closure plates are stamped. The magnetic circuit is formed by inserting I-shaped barrier plates between the outer arms of the E-shaped core plates. The lower and outer parts of the outer arms of the E-shaped core plates have openings into which, after packaging of the lamellae in the already known manner 3 71210, the tension rail can be gripped by its bent longitudinal edges.

Since in the stamping method according to the invention the outer edges of the outer arms are opposite, both openings can be stamped with the same blade, so that the stamping tool is also made more balanced. In addition, the advantage of this stamping method is that, in addition to the above-mentioned openings, another opening for the air gap part of the middle arm of the E-shaped core plate can be stamped with the same blade by means of an additional structure made therein.

A method is also known for producing E-shaped core plates and L-shaped closing plates placed between these two arms, in which two rows of E-shaped core plates are stamped with the free sides facing each other and against each other (DE-OS 2 638 780). In this method, the ends of the interconnected outer arms of two adjacent E-shaped core plates are joined together and the space between the outer arms above the center arm of the E-shaped core plate is filled with two L-shaped and rectangular closed plates. However, the disadvantage of this manufacturing method (E-shaped core plate and L-shaped closure plates) is that the plate package is three-part, so that it is not strong enough because the L-shaped central parts can turn upside down.

The stamping method according to the invention can advantageously be designed in such a way that the I-shaped closing plate is made longer than the free space between the E-shaped core plate outer arms. In this case, the package consisting of I-shaped closing plates can be pushed tensioned between the outer arms. The same can also be achieved by stamping the ends of the i-shaped barrier plate at an angle. An additional advantage of this is that the I-pack is easier to insert between the outer arms of the E-pack.

In some cases, it may be useful to increase or decrease the space for the coil. This can be solved by either increasing or decreasing the width of the I-shaped barrier plate. When stamping in this way, a larger or smaller opening is obtained between the outer arms and the middle arm of the E-shaped core plate, if necessary, without loss of plate material. The stamping method according to the invention is mainly used for the production of a choke with a low structure, whereby no material loss occurs. In some cases, however, a higher choke is required while the width remains the same. As a result, the combined length of the center arm and the outer arm of the E-shaped core plate relative to the free space required for stamping the I-slit closure plate is greater than the length of the I-shaped closure plate, whereby the material loss is small.

Another main advantage of the stamping method according to the invention is that when using an air gap between the middle arm of the E-shaped core plate and the I-shaped closing plate, the outer arm lengthens due to the shortening of the middle arm po. by an air gap, resulting in a larger coil space without additional material.

Other advantages and details of the invention will become apparent from the following description of some structural examples, with reference to the accompanying drawings.

Fig. 1 schematically shows a choke with core and barrier plates made by the method according to the invention, Fig. 2 illustrates po. the arrangement of the choke E-core plates and I-closure plates when applying the lossless stamping method according to the invention, Fig. 3 shows an E-shaped core plate and an I-shaped closure plate with sloping ends made by the method according to the invention, and Fig. 4 shows E-core plates and The order of the I-barrier plates in the above-mentioned stamping method.

The choke shown in Fig. 1 has an iron core comprising E-shaped core plates 1 and I-shaped closing plates 2. The central arms 3 of the E-shaped core plates 1 are connected to a coil 4 which, after winding, is pushed onto the E-core plate package. Between the I-shaped closure plate 2 and the central arm 3 of the E-shaped core plate 1, a deformable air gap portion 4a is disposed, which extends into the groove 5 in the central arm 3. The groove prevents the air gap portion 4a from moving away from the center so that no more eddy current loss. When a tension rail 7 is placed on the resulting structure between the outer arms 6 of a package of I-shaped closing plates 1, the longitudinal edges 8 of which are bent upwards and inwards around the ends of the outer arms 6 and in the notches 9 therein.

Figure 2 shows the production of E-core plates 1 and I-closure plates 2 for the choke of Figure 1 from the same sheet metal strip, without material loss. For stamping, the E-shaped core plates 1 are arranged opposite each other and also displaced so that the other end 10 of the outer arms 6 of the two E-shaped core plates 1 always contacts the end of the middle arm 3 of the opposed E-shaped core plate 1.

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When the opposite E-shaped core plates 1 have been moved in this way, two I-shaped closing plates 2 are always obtained by performing stamping in the spaces between the outer arms 6 and the middle arm 3.

It can further be seen from Fig. 2 that the notches 9 in the outer arms 6 and the groove 5 in the middle arm 3 for the air gap portion 4a can be stamped with the same blade because the order of the E-shaped core plates 1 has been shifted.

According to Fig. 3, the ends of the I-shaped closing plates 2 are recessed (11) so that the I-packages are easier to push and press more firmly between the outer arms 6 of the E-package. The oblique structure 11 is, of course, repeated as the bevel 12. In the E-shaped core plate 11, although this is practically irrelevant.

Figure 3 shows the order of the E-shaped core plate 1 and the I-shaped sealing plates 2 in the low material loss Stans drying method. The combined length of the central arm 3 and the outer arm 6 of the E-shaped core plate 1 is larger than the length of the I-shaped closure plate relative to the free space (for stamping the I-shaped closure plate), whereby material waste A is generated.

Claims (8)

A method for producing E-shaped core plates (1) and suitable I-shaped end plates (2) between its arms (3, 6) in a choke or transformer, in particular for use as a ballast device for gas discharge lamps, wherein in the outer the arms (6) of the E-shaped core plates possibly formed recesses (9) around which a clamping rail (7) is formed, characterized in that two rows of E-shaped core plates (1) are punched out with the open sides opposite and opposite each other and half the length with respect to the center axis relatively offset in such a way that the end (10) of each outer leg (6) of two adjacent E-shaped core plates (1) abuts at the end of the middle arm (3) in the opposite the offset E-shaped core plates and the I-shaped end plates (2) are punched out of the free spaces emerging between the outer arms (6) and the center arms (3) of the opposing E-shaped core plates (1). Method according to Claim 1, characterized in that the I-shaped endplate (2) at the punching is dimensioned longer than the internal dimension between the outer arms (6) in the E-shaped coreplate (1). Method according to claims 1 and 2, characterized in that the ends of the I-shaped end plate (2) are punched with a bevel (11). Method according to claims 1-3, characterized in that the recesses (9) on the outer arms (6) of the E-shaped core plates (1) of the clamping rail (7) are punched with the same punch. Method according to claim 4, characterized in that the lock (5) in the middle arm (3) of the E-shaped core plate (1) for receiving an air gap insert (4a) is punched together with the recesses (9) for the clamping rail (7) with same punch. 6. A method according to claims 1-3, characterized in that the I-shaped end plate (2) is in each case punched out with a width adapted to the required winding space. Method according to claims 1-3 and 6, characterized in that, if required, an air gap in magnetic