DE9012340U1 - Resistance device - Google Patents

Description

GR 89 G 3478 DE Ol

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Siemens AG'

Resistance device
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The invention relates to a resistance device according to the preamble of claim ¹ .

Such a resistance device is known from DE-AS 25 27 881 • 10.

The invention is based on the object of developing a resistance device of the generic type in such a way that the arrangement of the resistance elements is possible with other components.

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I The solution to the problem posed is achieved by the features specified in the characterizing part of claim 1.

&idigr; Based on an example of implementation shown in &~&tgr; drawing

20 game, the invention is described in more detail below. ■■ ^r shows:

': FIG 1 a resistance device in section,

FIG 2 an insulating body for fixed bearing,

I 25 FIG 3 an insulating body for plain bearings,

/ FIG 4 an insulating body with higher dielectric strength,

I FIG 5 a plan view of a sheet metal strip.

i 1 and 2 denote two resistance elements of a resistance device 3. The resistance elements 1 and 2 consist of meander-shaped folded sheet metal strips 4. A retaining projection 6 or 7 is arranged at each deflection point 5 of the meander-shaped folded sheet metal strips 4. With these

The resistance elements 1 and 2 * 35 are held by retaining projections 6 and 7 on insulating elements 11 and 12 arranged on support bolts 8, 9 and 10.

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GR 89 G 3478 DE Ol

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The resistance elements 1 and 2 are fixedly mounted on the support bolts 8 and IG located on the outside of the two resistance elements 1 and 2. In order to achieve such a fixed mounting in a simple manner, the holding projections 6 attached to the relevant side of the resistance elements 1 and 2 have a bore 13 with which these holding projections 6 are placed on an axial shoulder 14 of the insulating elements 11 for the fixed mounting, the diameter of which is adapted to the bore. The resistance elements 1 and 2 are slidably attached to the support bolt 9 located between the two resistance elements 1 and 2 by means of their half projections 7. For this purpose, a slot 15 is provided on the retaining projections 7, with which the retaining projections 7 are plugged onto an axial projection 16 of the insulating elements 12 for the plain bearing, the diameter of which is adapted to the width of the slot 15.

Since the two resistance elements 1 and 2 are jointly attached to the support bolt 9 located between them, there are twice as many attachment points on this support bolt 9 as on the external support bolts 8 and 10. For this reason, the insulating elements 12 for the sliding bearing arranged on the inner support bolt are only half the length of the insulating elements 11 for the fixed bearing arranged on the external support bolts 8 and 10.

In terms of shape, the two insulating elements 11 and 12 nevertheless match, since an axial projection 14 or 16 of the same size is formed onto the base bodies 17 of the insulating elements 11 and 12, which have different lengths. The insulating elements 11 and 12 therefore have a shape that allows simple and inexpensive production even when the insulating elements 11 and 12 are made as ceramic parts.

GR 89 G 3478

To increase the voltage resistance, it may be necessary to increase the creepage distances between the separation points of the lined-up insulating elements 11 and 12. In the case of an insulating element 18 shown in FIG. 4, an annular collar 19 extending radially outwards is formed on the base body 17 to increase the creepage distance. This annular collar is arranged centrally on the base body 17. Such insulating elements 18 are arranged in particular in the end region of the support bolts 8, 9 and 10, since this is where the greatest voltage stresses occur.

The insulating elements 11 and 12 are advantageously cylindrical. A cylindrical

i. form a cylindrical ring collar 19, as shown for the insulating elements 18. The cylindrical shape of the insulating elements 11, 12 and 18 themselves and, if necessary, also of the ring collar 11 allows the ceramic insulating elements 11, 12 and 18 to be manufactured using press technology without any further processing.

Claims (3)

GR 89 G 3478 DE Ol Protection claims .. &igr;&igr; 1. Resistance device in which two resistance elements (1 | 2) consisting of meander - shaped folded sheet metal strips (4) are arranged. and 2) between three support bolts (8-10) on which insulating elements (11 and 12) having the same contour are arranged, and at each deflection point (5) of the meanders, retaining projections (6 and 7) extending towards the support bolts (8-10) are attached to sheet metal strips (4), wherein the Side of the resistance element (1 and 2) arranged! retaining projections ( ') slide and the retaining projections (6) arranged on the other side of the resistance element ( ¹ and 2) are fixed
on axial projections (14 or 16) of the insulating elements (11 or 12)
are stored, characterized by that both resistance elements (1 and 2) with their corresponding retaining projections (7) are slidably mounted on the insulating elements (12) of the support bolt (9) lying between them and are fixedly mounted on the insulating elements (11) of the respective external support bolt (8 or 10), whereby the insulating elements (11) | for the fixed mounting of the retaining projections (6) are twice as long as the insulating elements (12) for the sliding bearing of the _retaining projections (7). * 2. Resistance device according to claim 1, characterized characterized in that the axial projections (14 and 16)
all insulating elements (11 and 12) have the same diameter. 3. Resistance device according to claim 1 or 2, characterized ^ in that the insulating elements f (18) a radially projecting annular collar (19) is formed.