NO121406B - - Google Patents

Description

Electrically shielding tape.

The invention relates to electrically shielding tape comprising a body of insulating material in which is inserted a continuous tape-shaped insert of electrically conductive material,

In electrical and electronic communication and instrumentation, it is very important that signals in nearby circuits are not mixed with each other and that they are protected against the influence of external magnetic fields. This is usually achieved by surrounding insulated conductors with an electrically conductive wire cloth armouring. External fields produce eddy currents in the shielding, which are led to earth if the shielding is earthed. In the past, such wire cloth shielding has been pulled over the insulated conductors to be shielded, or wrapped around these, or formed directly by braiding.

According to the invention, the tape of the type mentioned at the outset is characterized by the fact that the tape-shaped insert has two exposed parts situated close to the edges of the tape which run in the longitudinal direction of the tape on opposite sides thereof, so that the insert when winding the tape with overlapping edges around a cable or the like. forms a continuous rudder-shaped screen by the exposed parts near the overlapping edges coming into electrical contact with each other.

The tape according to the invention enables insulation and shielding of a conductor to be carried out in a simple and easy operation, if necessary at the workplace.

The invention shall be described in more detail in connection with an example with reference to the drawing, where

in

fig. 1 perspectively shows part of a band according to an embodiment of the invention,

fig. 2-4 are cross-sections showing alternative embodiments, and

fig. 5 is a perspective similar to fig. 1 and shows an outermost embodiment.

In fig. 1 denotes a body of insulating material, preferably a plastic or an elastomeric material. Of the many applicable materials, silicone rubber has proven to be the most advantageous, especially silicone rubber which has been designed so that it is self-adhesive. If an insulating material is used that does not have this property, a suitable adhesive can be applied to the tape before it is used.

A strip-shaped insert 12 of conductive material is inserted into the insulating body 10. This insert 12 extends through the band 10 of insulating material and is thus bent so that exposed areas 14 and 16 are obtained close to opposite side edges of the band. The conductor 12 comprises a planar middle part 18 whose edges 20,22 are designed for appropriate insertion into the band 10 and extend away from the surfaces 14 and 16 respectively which are exposed.

These areas 14 and 16 lie flush with the tape's side surfaces

and lies in such a way that when winding the tape with overlapping edges around an electric cable or the like, the areas 14 and 16 will lie against each other for overlapping pairs of edges, so that contact is made which provides a continuous electrical shielding. The insert 12, which forms the shielding, can be connected to earth or to a return circuit.

In fig. 2, the insert 12a is inserted into the insulating band 10a without any bending, as the insert is completely flat. Two areas 14a and 16a of the insert 12a on opposite side edges of the band are exposed by arranging channels in the insulating band 10 on opposite sides thereof near the edges of the band. The tape has a projecting line 24 at its center to serve to facilitate winding of the tape with the degree of overlap necessary to ensure electrical contact between the exposed areas 14a and 16a.

It will be understood that for simplification of the drawing, fig. 2, as well as the other figures, not drawn up to the correct scale. In particular, the thickness of the band in each of the examples shown is greatly exaggerated. In practice, the insulating band 10 will be quite thin, so that just wrapping the band around an insulated conductor will cause sufficient flow of the insulating material away from the channels shown in fig. 2 to ensure direct electrical contact between the exposed areas 14a and 16a for the insert 12a.

The design according to fig. 3 also makes use of an insert 12b which is not bent lengthwise. The insulating band 10b is applied as two separate strips on each side of the insert 12b, each strip having a width that is smaller than the insert 12b. In this way, exposed surfaces 14b and 16b are provided in incisions along the side edges of the insulating band 10b. Each of the insulating strips forming the band 10b ends in an edge to isolate the edges of the insert 12b.

The modification according to fig. 4 relates to a band which meets the requirements for a greater thickness than the normal one. The insulating band 10c has channels along opposite side edges, as in fig. 2, but strips 30 of conductive material are inserted in each of these channels. The strips 30 are in continuous contact with the areas 14c and 16c of the insert 12c in the respective channels,

and the exposed surfaces of the strips 30 are generally flush with the respective side surfaces of the tape.

In fig. 5 shows a band having tapered edges 32 and a center line 34 which lies flush with the band's surface. The tape 10d has maximum thickness in the middle and minimum thickness at the edges. The conductive insert 12d is similar to the insert 12 shown in fig. 1. The insert.12d thus has anchoring flanges along the edges. The tape's tapered edges and line 34 facilitate winding of the tape with proper overlap to ensure that direct electrical contact is made between the exposed surfaces 14d and 16d, respectively.

It should be noted that the dimensions of the tape.and. the choice of insulating and conductive materials will be determined by mechanical, electrical and assembly factors that are included in each particular application of the tape. The use of self-adhesive silicone rubber,

which was mentioned above as the most preferred material, is particularly recommended where cables or wires carrying low-frequency signals are to be shielded under a relatively hc-y working temperature. Under such application, the conductive insert can advantageously be a flattened braid or Monel metal.

Although here only reference is made to overlapping winding of the tape, it will be understood that according to the invention the tape can also be laid in the longitudinal direction\around electrical conductors or groups of conductors.

Shielding tape according to the invention can be produced in different ways. Preferred methods of preparation are described in U.S. Pat. patent 3,253,073 and 3,439,383.

The tape can be made by first extruding plastic through an extrusion die onto a plate of metal or other moving material, to which plate the plastic will not adhere permanently. A narrow strip of metal is moved past the nozzle opening, the strip being stretched over the rounded nose of the nozzle. At the same time, the plastic is pushed out of the opening towards the underside of the metal strip to cover one side of this, apart from an edge section. The plastic-coated metal strip is laid with the coating facing upwards on the plastic that has been extruded on the temporary support, with the uncoated side of the metal strip being laid on and somewhat laterally offset relative to the extruded plastic so that an edge section on the other side of the strip is also not coated. An appropriate pressure device is then placed over the coating on the strip to transfer the coating from the temporary support to the strip so that it is coated with a plastic layer on both sides. The tape can then be heat treated or otherwise hardened.

Claims (2)

1. Electrically shielding tape comprising a body of insulating material in which is laid a continuous tape-shaped insert of electrically conductive material, characterized in that the tape-woven insert (12) has two exposed parts (14,16) located near the edges of the tape which continue in the longitudinal direction of the tape on opposite sides of this, so that the insert when wrapping the tape with overlapping edges around a cable e.l. forms a continuous rudder-shaped screen by the exposed parts near the overlapping edges coming into electrical contact with each other. 2. Tape as specified in claim 1, characterized in that the insert (12, 12d) has a continuous flange (20, 22, 20d, 22d) running along each edge inserted into the insulating material (10, 10d) to anchor the insert ( 12, 12d).