DE8914500U1 - Extruded heat shrinkable component with multiple passage channels - Google Patents

Description

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Heat-shrinkable components and their use for producing electrical conductor connections are known from DE-PS 25 39 275. These components consist of a heat-shrinkable tube and a non-heat-shrinkable spacer made of a plastic with a high softening point arranged inside this tube. This space divider preferably has a cross-shaped cross-section so that the inside of the heat-shrinkable tube is divided into visibly longitudinally extending channels. At least two electrical conductors can be accommodated in each of these four channels.

In addition, the known heat-shrinkable component contains a melting conductive material in the form of a solder, with the help of which the conductors contained in the same longitudinal channel are connected.

This known component, which contains a heat-shrinkable, extrudable tube and a non-heat-shrinkable space divider, can only be manufactured with considerable effort, since the shrinkable tube and the non-shrinkable space divider are made of materials with significantly different behavior and must be manufactured and assembled in separate production steps.

Furthermore, after shrinking, the longitudinal channels in which the conductors are arranged are not closed, so that gases or moisture can penetrate into these channels and flow through them. Since the outer shrink tube does not fit tightly against the electrical conductors contained in the channels after shrinking, these conductors are not clearly positioned in the known component.

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Furthermore, it is known, for example, in the manufacture of weldable plugs, to lead the conductors belonging to the plug through a sleeve consisting of an insulating tube and then to locally fill the inner surface of the sleeve with rubber and then a filler in order to fix the conductors in the insulating tube on the one hand and to fill the gaps between the conductors and the gaps between the conductors and the insulating tube on the other.

Because of the injection processes, this known method is extremely cost-intensive.

The innovation is based on the task of creating a heat-shrinkable component with a large number of through-channels running parallel to one another in the longitudinal direction, which can be produced cost-effectively and has particularly advantageous properties for use as a sleeve for electrical conductors or the like.

,| This object is achieved by the invention specified in claim 1.

'. The subject of the present invention is a heat-

shrink-fitting component with at least two through-channels running parallel to one another in the longitudinal direction and separated from one another by means of inner walls. According to the invention, this heat-shrinkable component, together with its inner walls, is formed in one piece by extrusion.

The progress that can be achieved with the help of the innovation results primarily from the fact that the entire component is made in one piece in the form of an endless shrink tube with longitudinal channels formed in it.

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Furthermore, with the help of the new one-piece component, a separate chamber (through channel) is provided for each electrical conductor.

The accommodation of electrical conductors in the innovative component includes the further advantage of a defined outer diameter of the component, which is advantageous for later overmolding of the component accommodating the conductors. The inner walls of the innovative component each form an insulation, so that the individual chambers formed by the through-channels are electrically insulated from one another.

Furthermore, the use of the heat-shrinkable component according to the invention allows a clear positioning of the conductors within this component as well as a positioning of the component according to the invention in an outer sheath, for example an outer insulating tube.

By selecting a suitable heat-shrinkable material, a high thermal load capacity can be achieved. Because the component according to the invention is made in one piece and is therefore made of a uniform material, the required high thermal load capacity can be ensured in the entirety of the component according to the invention. ^|

Materials that are usually used for shrinking materials, such as polyolefins, elastomers, etc., can be considered as shrinkable materials for the extruded component according to the invention.

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The extruded heat-shrinkable component according to the invention is particularly suitable for fixing electrical conductors in a predetermined manner and protecting them in this fixed position against corrosion, for example by corrosion caused by longitudinal water.

Preferred embodiments of the innovation are specified in the subclaims.

The innovation is described in more detail below using examples and with reference to the drawing.

In this shows:

Fig.1 a perspective view of an extruded heat-shrinkable component before shrinking,

Fig.2 a perspective view of the in Fig. 1

shown component with electrical conductors arranged in the through-channels after shrinking and

Figures 3A to 3J show preferred cross-sectional shapes of the component Is.

The heat-shrinkable component 1 shown in Fig. 1 is manufactured in one piece, together with its inner walls separating a large number of passageways 2, using an appropriately designed extruder nozzle. The component 1 has an essentially rectangular cross-sectional shape with rounded corners (edges). The wall thicknesses (outside and inside) correspond to the wall thicknesses of conventional heat-shrinkable components. However, it should be noted that

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knit that heat-shrinkable components with multiple longitudinal passageways have not yet been manufactured by extrusion.

Fig. 2 shows the component shown in Fig. 1 with one electrical conductor 3 per through-channel 2. After the conductors 3 have been introduced into the through-channels, the component 1 with the electrical conductors accommodated therein has been subjected to a shrinking process. During this shrinking process, the component 1 has shrunk primarily in the radial direction, which means that each electrical conductor 3 is tightly shrunk around the component 1. This shrinking of the electrical conductors is so tight that liquids, such as longitudinal water, have no chance of penetrating the area of the component 1 and spreading there on the conductors.

If the component shown in Fig. 2, together with the electrical conductors 3 accommodated therein, is surrounded by an outer sheath/ such as an outer insulating tube/, the component 1 in such a tube forms a perfect seal as well as a perfect fixing element for the electrical conductors.

The extruded heat-shrinkable component according to the invention can be manufactured in a wide variety of different cross-sectional shapes and through-channel arrangements. Only nine exemplary embodiments are given in Fig. 3. Thus, Fig. 3A shows a component 1 with a triangular cross-sectional shape and with three through-channels 2 extending in the longitudinal direction of the component, which are also arranged in a triangular pattern. The channels have a circular shape.

Fig. 3B shows the cross-sectional shape of the component 1 illustrated in the figures with a substantially

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rectangular cross-sectional shape »with rounded edges and four through-channels 2, which also have a substantially rectangular cross-sectional shape and rounded corners. The four channels 2 according to Fig. 3B are arranged in pairs next to each other or one above the other.

Fig. 3C shows a component 1 with a circular cross-section, in which seven through-channels 2 are arranged at equal distances from one another in this circular cross-section. One channel is located directly in the center of the circular cross-section and six channels surround this central channel at equal distances. In the embodiment shown in Fig. 3C, each of the channels has a circular cross-section. It is understood, however, that not all of the through-channels provided in a component 1 have to have the same cross-section.

Thus, Fig. 3D shows that the component 1 can have an elliptical cross-sectional shape, wherein a through-channel 2 with a circular cross-section is arranged near the two outer ends of this elliptical shape and a through-channel ²¹ with an elliptical cross-sectional shape is arranged in the region of the center of the ellipse.

Fig. 3E shows a cross-section of an essentially rectangular component 1 with four through-channels 2 arranged in the area of the center line (not shown) of this component, each with a circular cross-section.

For all components according to the invention, it is not necessary for all through-channels 2 to be occupied by electrical conductors. Through-channels not occupied by electrical conductors can be used as channels for gases or liquids.

In Fig. 3F, a component 1 with a triangular cross-sectional shape is shown, in which, however, in contrast to the embodiment according to Fig. 3A, the three through-passage channels 2 have a triangular cross-sectional shape. These triangular through-passage channels are arranged in a triangular arrangement in the cross-sectional area of the component 1.

In Fig. 36, a component 1 with a polygonal cross-sectional area is shown, namely a cross-sectional area in the form of a regular hexagon, with three through-channels 2 with a circular cross-section being arranged on a hexagon in this cross-sectional area. It is understood that instead of a hexagonal cross-sectional shape, another polygonal cross-sectional shape can also be provided and that the through-channels can be arranged in a different arrangement to one another than that shown in Fig. 36; for example, in a triangular arrangement as in Figures 3A and 3F.

Furthermore, Fig. 3H shows a cross-sectional shape of a component 1, which is essentially square. As in Fig. 30, the outer corners (edges) of the component 1 are rounded. In the cross-sectional area, four through-channels 2 with a circular cross-sectional shape are arranged in two rows next to one another or one above the other.

Fig. 3J shows a cross-sectional view of the component 1 with a through-channel 2 of cross-sectional view which is arranged in a rectangular glass-panel and in accordance with Fig. 3H.

The design of the measuring device Figure 1 is not limited to the models 3A to 3J. It shows cross-section shapes and channel shapes as well as channel arrangement patterns.

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Claims (5)

1. Heat-shrinking component with at least two passage channels running parallel to each other in the longitudinal direction and separated by means of internal walls, characterized in that the heat-shrinkable component (1) including the through-channels C2) separate from each other Inner walls made of a single material and that the component, including its inner walls, is formed in one piece by extrusion. 2. Component according to claim 1, characterized in that it has a triangular, square, circular, elliptical, rectangular or polygonal cross-sectional shape. 3. Component according to claim 1 or 2, characterized in that the through-channels (2) have a circular, a square, a triangular or an elliptical cross-sectional shape. 4. Component according to claim 3, characterized in that through-channels (2, 21) of different cross-sectional shapes are provided in a component (1) 5. Component according to one of claims 1 to 3, characterized in that the plurality of through-channels (2, 21) are arranged in regular geometric patterns, such as a triangular pattern, a square pattern, a circular pattern or in a corresponding direction in the component. &bull; Il Il I III ti If &bull; I I I I I 1*1 &bull; *l < ItI(I «ti t ·*I &igr; tin it # I I &bull; (IIIIII t i I« lit I III »I Il