NL9400338A - Cable for electrical and optical signals - Google Patents

Abstract

Cables intended for the transmission of both electrical signals or electrical power and optical signals, comprising a first electrical conductor which is designed as a hollow, cylindrical element made of electrically conducting material, a second electrical conductor disposed within the first electrical conductor and at least one optical conductor which is disposed in the space between the two electrical conductors.

Description

Cable for electrical and optical signals

The invention relates to a cable intended for the transmission of both electrical signals or electrical energy and optical signals, comprising: a first electrical conductor which is designed as a hollow cylindrical element of electrically conductive material, a second electrical conductor arranged within the first electrical conductor and at least one optical conductor disposed within the first electrical conductor.

Such cables are known from the prior art. Examples thereof are described in US-5.150.442, US-4.895.426, EP-0.516.931, EP-0.483.338, JP-64.41117, JP-01.43908 and JP-63.301419. In all these known cables, the second electric conductor is also designed as a hollow cylindrical element of electrically conductive material which is arranged concentrically within the first conductor. Furthermore, in all these known cables, the at least one optical conductor is disposed within the second electrical conductor in the center of the concentric configuration.

Cables of the above type can be used in those situations where the signal transmission takes place via the optical conductors, but at the same time, for example for the electrical supply of the signal processing equipment, electrical voltage is required. In order to avoid having to draw the electrical voltage via separate cables from the electricity network, both the optical conductors and the electrical conductors are combined in a single cable. Such cables are particularly advantageous when building communication networks, because with only one cable both the necessary electrical voltage can be supplied to each terminal and signals can be transferred between the various terminals.

A drawback of the above-mentioned known cables is that use is made of two or even more concentric, hollow, cylindrical, electrical conductors with one another. This construction makes the cable as a whole relatively stiff, which is disadvantageous especially in communication networks, because it often has to be possible to lay cables in short bends.

Certainly if the cable is used in applications such as a network, in which a relatively large number of terminals have to be electrically supplied and therefore relatively large currents will flow through the electrical conductors, the copper cross section of the conductors must be chosen relatively large in order to avoid excessive electrical losses. avoid the cable. This can lead in particular that the inner hollow cylindrical electrical conductor must have a relatively great thickness, with the result that the stiffness of the cable increases even further.

A further problem may lie in the fact that the relatively weak and fragile optical guides are in the center of the concentric configuration. From a technical point of view, it is often much simpler if there is a relatively strong element in the center, such as an electrical conductor or a strength element, which can serve as a basis during the manufacture of the cable.

The object of the invention is now to provide a cable of the type mentioned in the preamble, wherein the above-mentioned drawbacks of the known cables are avoided. This object is met by a cable of the type mentioned in the preamble, which according to the invention is characterized in that the at least one optical fiber is arranged in the gap between the two electrical conductors.

By positioning the at least one optical fiber in the interspace between the two electrical conductors, it is avoided that the relatively weak and sensitive optical conductor must be used as a basis during manufacture. Instead, the second conductor, which is designed as a cylindrical element of electrically conductive material, can now be used as a basis. This second conductor will have sufficient strength to serve as the basis for manufacturing the entire cable in a manufacturing process.

It is preferable that a number of cylindrical elements which are at least partly formed by encapsulated optical conductors and at least partly formed by filling elements are present in the space between the two electrical conductors around said second conductor. By using a number of cylindrical elements in the gap between the two electrical conductors, this gap is filled in such a way that a good fixation of the gap is achieved. It is particularly preferred that so many cylindrical elements are used that, when positioned side by side around the inner conductor, they substantially fill the gap.

If filling elements are used, various materials are suitable for this. However, it is preferable that the filling elements are designed to serve as a strength element.

In connection with good insulation between the electrical conductors, it is preferred that an inner jacket of electrically insulating material is present against the inner wall of the first electrical conductor.

A further improvement of the insulation can be achieved by designing the cable in such a way that a second inner jacket is arranged around the outside of the second electrical conductor.

Because of the external protection of the cable, it is preferable that an outer sheath of electrically insulating and water-impermeable material is arranged around the outside of the first electrical conductor.

The invention will be further elucidated hereinbelow with reference to the annexed figures, in which various embodiments of a cable according to the invention are illustrated.

Figure 1 shows a section through a first embodiment of a cable according to the invention.

Figure 2 shows a second embodiment of a cable according to the invention.

Figure 3 shows a third embodiment of a cable according to the invention.

Figure 4 shows a fourth embodiment of a cable according to the invention.

The cable shown in section in Figure 1 includes a first electrical conductor 10, which is constructed as a hollow cylindrical element of an electrically conductive material. A second electrical conductor 12 is located in the center of the cable. On the one hand, a number of filling elements 14 are provided in the space between the two conductors 10 and 12 (of which only one is referenced in figure 1 for the sake of clarity), as well as a number of light conductors 16, each provided with an envelope 18 ( reference numbers 16 and 18 are also shown only once in the figure for the sake of clarity). The remaining space between the guides 10 and 12, which is not occupied by one of the filling elements 14 or by one of the optical guides 16, 18, can optionally be filled with a suitable filling mass 20. Such filling masses are known per se and will not be discussed further. An outer jacket 22, which preferably consists of an electrically insulating and impermeable material, can be arranged around the first electrical conductor 10. Such outer jackets and suitable materials for manufacturing them are also known to a person skilled in the art.

A second embodiment of the cable according to the invention is shown in cross-section in figure 2. This embodiment also contains a first electric conductor 10, designed as a hollow cylindrical element of electrically conductive material, a second electric conductor 12, which is positioned in the center of the cable, a plurality of fillers 14 located in the space between the first electrical conductor 10 and the second electrical conductor 12 and a plurality of optical conductors. In this exemplary embodiment, the optical conductors are bundled in different numbers, each within a protective jacket. Within the jacket 18a there is only one optical guide 16a. Within the jacket 18b, however, are three optical guides 16b, 16c and 16d. It will be clear that the number of optical conductors can be freely chosen within limits. An outer jacket 22 is also present in this embodiment. In addition, an inner jacket 24 of electrically insulating material is arranged against the inner wall of the first electrical conductor 10. Such a jacket considerably increases the insulation between the two electrical conductors, in particular in the case, for example, that the filling mass 20, which is arranged in the remaining space between the two electrical conductors, naturally has a relatively low electrical insulation value.

Figure 3 shows a section through a third embodiment of a cable according to the invention. Also this embodiment is provided with a first electrical conductor 10, a second electrical conductor 12, a number of optical conductors 16, each arranged in a protective enclosure 18, an outer jacket 22 and an inner jacket 24, all designed as previously described in the preceding figures. In this embodiment, a further inner sheath 26 is disposed around the second electrical conductor 12. Furthermore, the sheaths 18 of the various optical fibers 16 are dimensioned such that these sheaths fit snugly into the cylindrical space between the first inner sheath 24 and the second inner sheath 26. The number of envelopes (and thus also the number of optical fibers) is further chosen such that the available cylindrical space between the two inner jackets 24 and 26 is at least approximately utilized. The remaining gaps can again be filled with a filling mass 20.

Also in the embodiment of Figure 4, the first electrical conductor 10, the second electrical conductor 12, a plurality of fillers 14, a plurality of optical fibers 16 are each provided within a protective envelope 18, an outer jacket 22, an inner jacket 24, and filler mass 20 In contrast to the embodiments shown in Figures 1, 2 and 3, in this case, the second electrical conductor 12a is not constructed as a solid wire of electrically conductive material, but as a layer of electrical material applied to a central strength element 12b. Such an embodiment can for instance be used in applications in which the currents through the electrical conductors are relatively low, so that a thin layer of electrically conductive material on a central strength element is already sufficient to carry these currents without much loss.

In the above, the cylindrical elements 14 are designated by the term "fillers". It will be clear to those skilled in the art that these fillers may either consist of a relatively inexpensive filler material that exhibits approximately the same properties in shape resistance as the protective sheaths 18 of the optical guides 16, but in many cases it will be preferred that the fillers 14 made of such a material that these elements can serve as a strength element. Consider in this connection the use of thin cables of glass fiber or aramid fiber.

Claims (11)

Cable intended for the transmission of both electrical signals or electrical energy and optical signals, comprising: a first electrical conductor which is designed as a hollow cylindrical element of electrically conductive material, a second electrical conductor arranged within the first electrical conductor and at least one optical conductor disposed within the first electrical conductor, characterized in that the at least one optical fiber is disposed in the interspace between the two electrical conductors. Cable according to claim 1, characterized in that in the interspace between the two electrical conductors around the said second electrical conductor a number of cylindrical elements is present, which are at least partly formed by optical conductors provided with an envelope and at least partly formed by filling elements. Cable according to claim 2, characterized in that the diameter of the filling elements and the diameter of the envelope of the optical conductors is substantially the same. Cable according to claim 2 or 3, characterized in that the dimensions and the number of cylindrical elements (filling elements and sheathed optical conductors) are chosen such that these elements are positioned at least approximately in section in a layer within a cylindrical space coaxial about the second electrical conductor. Cable according to any one of claims 2 to 4, characterized in that at least some of the filling elements are designed in such a way that they serve as a strength element. Cable according to any one of the preceding claims, characterized in that an inner sheath of electrically insulating material is present against the inner wall of the first electric conductor. Cable according to any one of the preceding claims, characterized in that an inner sheath of electrically insulating material is arranged around the outside of the second electric conductor. Cable according to any one of the preceding claims, characterized in that an outer jacket of electrically insulating and water-impermeable material is arranged around the outside of the first electrical conductor. Cable according to any one of the preceding claims, characterized in that the remaining space between the two electrical conductors is filled with a water-impermeable mass. Cable according to any one of the preceding claims, characterized in that the second electrical conductor is designed as a solid cylindrical conductor. Cable according to any one of the preceding claims, characterized in that the second electrical conductor is constructed as an electrically conductive layer which is arranged around a strength element placed centrally in the cable.