DE8806594U1 - Shade slat - Google Patents

Description

I · I

1
UMBRELLA BLADE

Description

The invention relates to a shielding lamella for installation as a ground spring ring in a connector, with two opposing edge strips which are connected to one another by a plurality of curved spring strips running transversely thereto and spaced from one another, the spring strips being curved in their strip plane.

Shielding strips are used in connectors to create a ground connection between the socket housing and the plug housing and to shield the line connection against external interference voltages. To do this, the shielding strip must be able to create good electrical contact between the socket housing and the plug housing. On the other hand, it is necessary that the ground connection only has a low coupling resistance even after a large number of plug-in cycles of the connector. While the coupling resistance can be effectively reduced at the beginning by applying highly conductive coatings to the socket housing and the plug housing as well as to the shielding strip, problems often arise after just 100 plug-in cycles because the highly conductive surfaces of the shielding strips and the connector housing are mechanically torn open and become electrically poorer after a few days of rest due to the pollutants in the air; foreign layers form. The relatively low interference voltages that are supposed to be diverted via the shielding strip are not sufficient to break through these foreign layers.

A shielding strip of the type mentioned above is known from DE-OS 35 18 030. As with conventional shielding strips, the individual spring strips are curved radially outwards so that they are subjected to bending stress when the connector is plugged together. Since the spring strips are curved within the plane of the strip, the respective contact point moves between a spring strip and the plugged-on connector housing so that the wear of the highly conductive surface layers is as even as possible. Nevertheless, even with this shielding strip, the coupling resistance increases significantly after several hundred plug-in cycles of the connector.

The object of the present invention is to improve a shielding lamella of the type mentioned at the outset in such a way that with the lowest possible surface wear, the coupling resistance of a connector remains sufficiently low even after several hundred plug-in cycles.

This object is achieved according to the invention in that an edge of a spring strip in the strip plane between the connection points to the opposite edge strips is convexly curved to one side.

An electrical connection element is known from DE-OS 25 01 003 which provides individual strips running transversely between two edge strips with convexly curved edges on both sides. These strips are only twisted around their longitudinal axis, but not curved. The advantage achieved with the invention is that the individual spring strips are now not only subjected to bending or torsion, but to both bending and torsion. This results in the spring characteristic of a spring strip being much weaker than with known shield blades, since two springs are now connected in series for each spring strip, namely a bending spring and a torsion spring. This

This means that the damage to the highly conductive surfaces of the connector caused by the shielding strip is greatly reduced compared to conventional shielding strips. Despite the softer spring characteristic of the individual spring strips, a good ground connection is achieved between the connector housings, since there is only a line contact between the spring strips and the adjacent connector housing. This contact occurs via the convexly curved edge of each spring strip, which protrudes the furthest beyond the outer circumference of the shielding strip. Characteristic of this line contact is a high specific pressure force, which is responsible for the low coupling resistance.

According to a preferred embodiment of the invention, the space between two adjacent spring strips is designed in the shape of a crescent moon, so that the edge of a spring strip opposite the convexly curved edge is concavely curved. This makes the spring strip narrower, which on the one hand reduces its flexural rigidity and on the other hand increases the effective length of the spring strip.

If the gaps in the middle between the edge strips are wider than near the edge strips, this means that on the one hand, the spring strips are narrower in their middle than in the area of the edge strips, which makes the spring characteristic even softer, and on the other hand, that interference fields are better reduced.

It has proven to be particularly advantageous if the concavely curved edge in the middle of the spring strip is located outside an imaginary line connecting the two connection points of the spring strip to the edge strips. The spring strip thus protrudes a considerable distance to the side. This ensures in a simple way that only the outer, convexly curved edge

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Contact with the connector housing surrounding the shielding strip.

It is also particularly advantageous if the edge strips are connected tangentially to the spring strips, so that the planes of the opposing edge strips intersect. In this way, the edge strips only rest on the inner connector housing with one edge; the curvature of the spring strips therefore continues into the edge strips. This allows the effective length of the shielding lamella available for bending to be increased, since only the length of the spring strip and the widths of the two edge strips take part in the bending process when the connector is plugged together. The spring characteristic of the shielding lamella is thereby advantageously further weakened.

According to a preferred embodiment, at least one edge strip has recesses on its side facing away from the spring strip, in the area of the connection points of the spring strip. This ensures that the edge of the edge strip only rests against the inner connector housing with uniform pressure at the points where no recesses are provided. This promotes partially equal contact resistances around the shielding lamella.

It is also advantageous if at least one edge strip has retaining tongues that are spaced apart and projecting from one another on its side facing away from the spring strip. These retaining tongues can be mounted on the inner connector housing so that the edge strip rests in a sliding fit on a receptacle of the inner connector housing. This allows the spring characteristic of the shielding lamella to be further weakened. The shielding lamella is advantageously punched out of a sheet metal strip.

In the following, an embodiment of the invention is explained in more detail with reference to a drawing. They show:

Fig. 1 shows a schematic perspective view of a shielding lamella according to the invention before its installation in a connector,

Fig. 2 the development of a screen blade from Fig. 1,

Fig. 3 shows a section through an internal housing of a connector with an inserted shielding strip,

Fig. 4 in a similar view as in Fig. 3 a plugged connector and

Fig. 5 is a cross-section through a partially

shown connectors along the line V-V.

Fig. 1 shows a perspective view of a shielding lamella 1 according to the invention for installation as a mass spring ring in a connector. Fig. 2 shows a development of the shielding lamella 1 bent into a barrel-shaped body in Fig. 1.

The shield blade 1 has two circumferential, opposite edge strips 2 and 3, which are connected to one another by several spring strips 4 running transversely thereto and spaced apart from one another. The spring strips 4 are, on the one hand, curved, as can be seen from Fig. 1, 3 and 4, and, on the other hand, as is particularly clear from Fig. 2, they run curved in their strip plane. The curvature is designed in such a way that the outer edge 5 of a spring strip 4 between the connection points 6 and 7 is convex to one side relative to the opposite edge strips 2 and 3.

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is curved. The opposite edge 8 of a spring strip 4 is concavely curved. This means that the spaces 9 between two spring strips 4 take on the shape of a crescent moon. In the embodiment shown here, the radius of curvature of the concavely curved edge 8 is selected to be smaller than that of the convexly curved edge 5. This means that the spring strips 4 are narrower in the middle between the two edge strips 2 and 3 than in the area of the edge strips 2 and 3 and that the spaces 9 in the middle between the edge strips 2 and 3 are wider than in the vicinity of the edge strips 2 and 3. The curvature of the spring strips 4 is so strong that the concavely curved edge 8 in the middle between the edge strips 2 and 3 lies outside an imaginary line 10 which connects the connection points 6 and 7 of a spring strip 4.

An edge strip, here the edge strip 2 of the shield blade 1, has recesses 11 on its side facing away from the spring strip 4 in the area of the connection points 7. These recesses 11 cause the edge of the edge strip 2 to be interrupted. On the same edge strip 2, on the side facing away from the spring strip 4, retaining tongues 12 are arranged that are spaced apart from one another and protrude from the edge strip 2.

As can be seen particularly well from Fig. 4, the edge strips 2 and 3 merge tangentially into the spring strips 4, so that the planes El and E2 of the edge strips 2 and 3 intersect.

The sheathing plate 1 is assembled as shown in Fig. 2
The shield lamella 1 is then provided with a curvature (see Fig. 3 and 4). The retaining tongues 12 are then bent by approximately 90° and the metal strip is bent round so that the shield lamella has the barrel-shaped shape shown in Fig. 1.

takes shape. In this state, the shielding lamellas are sold as components for connectors. In the following, the function of the shielding lamella is explained in more detail based on its installation in a connector.

Fig. 3 shows an internal housing part 13 of a connector, with a casing surface 14 and an adjoining flange part 15. The casing surface 14 is limited on the one hand by a stop 16 and on the other hand by the flange part 15. A recess is formed in the flange part 15, which is limited radially on the outside by a further stop 17. The shielding blade 1 is now placed on the housing part 13 in such a way that the two edge strips 2 and 3 each rest with their edge on the casing surface 14. The retaining tongues 12 are held in the recess of the flange part 15 and allow the edge strip 2 to move away in the axial direction of the housing part 13 (see Fig. 4).

If an outer housing part 18 of the connector is pushed onto the inner housing part 13, the spring strips 4 are pushed together. The contact between the spring strips 4 of the shielding blade 1 and the inner cylinder surface 19 of the housing part 18 occurs essentially exclusively via the convexly curved edge 5 of the spring strips 4 (see Fig. 5). This is because the edge lies tangentially outside the imaginary line 10 at a distance a, as shown in Fig. 2. This distance a ensures that the edge 5 always comes into contact with the inner cylinder surface 19 of the housing part 18 first. The load acting on the edge 5 leads, on the one hand, to the spring strips 4 being pressed together, as shown in Fig. 4; the spring strips 4 are therefore subject to bending stress. Furthermore, the distance a of the edge 5 to the imaginary connecting line 10 causes the spring strip 4 to be twisted around the line 10. The spring strip 4 therefore acts simultaneously as a bending and as a

Torsion spring. From the sectional view in Fig. 5 it can be clearly seen that the individual spring strips 4 only rest with their outer, convexly curved edge 5 on the inner cylinder surface 19 of the housing part 18. It can also be seen that due to the convex curvature of the edge 5 when the two housing parts 13 and 18 are put together, the contact point between the edge 5 and the inner cylinder surface 18 does not occur on a line parallel to the axis, but rather that the contact point also moves in the circumferential direction of the cylinder surface 19.

The design of the shield blade described above means that the spring characteristic is greatly reduced since the spring strips now function both as a bending spring and

also act as a torsion spring, with these two springs in &igr;
&Ggr; row are connected in series. Since the edge strips 2

and 3 only with their outer edges on the lateral surface

' 14 of the housing part 13, the

The effective spring force available for bending the shield blade is fully utilized. Since no edge strip is firmly clamped, the spring characteristic of the shield blade is further weakened.

Despite this weakening of the spring characteristic, which is desired in order not to damage any surface coatings on the inner cylinder surface 19 of the housing part 18 even with large plug-in cycles of the connector, the line contact between the edge 5 and the inner cylinder surface 19 causes a very low coupling resistance between the housing parts 13 and 18.

Claims (8)

1 Umbrella protection claims 1. Shielding lamella for installation as a ground spring ring in a connector, with two opposing edge strips (2, 3) which are connected to one another by several curved spring strips (4) running transversely thereto and spaced from one another, the spring strips (4) being curved in their strip plane, characterized in that an edge (5) of a spring strip (4) is convexly curved to one side in the strip plane between the connection points (6, 7) to the opposing edge strips (2, 3). 2. Umbrella blade according to claim 1, characterized in that the intermediate space (9) between two adjacent spring strips (4) is formed in the shape of a crescent moon, so that the edge (8) of a spring strip (4) opposite the convexly curved edge (5) is concavely curved. 3. Umbrella blade according to claim 1 or 2, characterized in that the intermediate spaces (9) in the middle between the edge strips (2) are wider than in the vicinity of the edge strips (2, 3). 4. Umbrella blade according to one of claims 1 to 3, characterized in that the concavely curved edge (8) in the middle of the spring strip (4) lies outside an imaginary line (10) connecting the two connection points (6, 7) of the spring strip to the edge strips. 5. Umbrella blade according to one of claims 1 to 4, characterized in that the edge strips (2, 3) are connected tangentially to the spring strips (4), so that the planes (El, &Egr;3^ of the opposite edge strips (2, 3) intersect. 6. Screen blade according to one of claims 1 to 5, characterized in that at least one edge strip (2) has recesses (11) on its side facing away from the spring strip (4) in the region of the connection points (6, 7) of the spring strips (4). 7. Umbrella blade according to one of claims 1 to 6, characterized in that on at least one edge strip (2) on its side facing away from the spring strip (4) spaced apart and projecting retaining tongues (12) are formed. 8. Screen lamella according to one of claims 1 to 7, characterized in that the screen lamella (1) is punched out of a sheet metal strip.