DE9413136U1 - Coaxial radio frequency cable - Google Patents

Description

Description

The invention relates to a coaxial high-frequency cable with an inner conductor, with a tubular outer conductor arranged coaxially and at a distance from the inner conductor, and with an insulation made of foamed plastic that fills the space between the two conductors and serves as a spacer, in which at least one optical fiber running over the entire length of the high-frequency cable is arranged in the outer region of the insulation (GB-PS 1,470,890).

With such high-frequency cables - hereinafter referred to as "HF cables" - not only high-frequency energy or high-frequency signals can be transmitted via the optical fiber - hereinafter referred to as "LWL" for short - but also telecommunications signals on a separate transmission path. For example, information can be exchanged and control and regulation signals can be transmitted via the LWL. If the LWL is designed appropriately as a sensor cable, changes in the environment (temperature) of the HF cable can also be detected and transmitted to a monitoring point.

In the known HF cable according to GB-PS 1,470,890 described above, the optical fiber is inserted into a groove-shaped recess that is attached in a spiral shape in the foamed insulation. The effort required to manufacture this HF cable is considerable, since the recess must be created subsequently by cutting or sawing. Inserting the

LWL in the recess during the manufacturing process is problematic.

The invention is based on the object of simplifying the production of the RF cable described above.

This object is achieved according to the invention in that the optical fiber rests on the surface of the insulation and is at least partially pressed into the correspondingly deformable material thereof.

This HF cable can be manufactured using conventional technology. Before the outer conductor is formed, an optical fiber is simply applied to the core of the outer conductor, which consists of the inner conductor and foamed insulation. To do this, the optical fiber can be laid in a spiral around the insulation. However, it is also sufficient if the optical fiber is laid on the insulation in an irregular path, essentially in the lengthwise direction of the HF cable. In both cases, the optical fiber is enclosed by the outer conductor and, when it is formed into a tube, is at least partially pressed into the surface of the "soft" insulation.

Advantageous embodiments of the invention emerge from the subclaims.

Embodiments of the subject matter of the invention are shown in the drawings.

Show it:

Fig. 1 shows a cross section through an RF cable according to the invention.

Fig. 2 shows an embodiment of the RF cable in perspective view.

Fig. 3 shows a modified embodiment of the HF cable compared to Fig. 2.

Fig. 4 and 5 show different designs of the optical fiber used in the RF cable in an enlarged view.

The coaxial HF cable shown in Fig. 1 has an inner conductor 1, an insulation 2 surrounding it and serving as a spacer, and a tubular outer conductor 3. The inner conductor 1 and outer conductor 3 are preferably made of copper. The inner conductor 1 can be wire-shaped or tubular. The insulation 2 completely fills the space between the inner conductor 1 and outer conductor 3. It is made of foamed plastic, for example polyethylene. The foamed plastic of the insulation 2 is adjusted so that it is sufficiently firm to fulfill its function as a spacer. On the other hand, the plastic is "soft" enough so that it can be deformed when the outer conductor 3 is applied. The outer conductor 3, which is arranged concentrically to the inner conductor 1, can be designed as a smooth tube or as a corrugated tube with a corrugation running transversely to the longitudinal axis of the HF cable.

According to Fig. 1, there is an optical fiber 4 between insulation 2 and outer conductor 3. The optical fiber 4 was applied to the surface of insulation 2 before the outer conductor 3 was formed into a tube. The HF cable has at least one optical fiber 4. However, there can also be two or more optical fibers 4, which can be arranged individually next to one another or at different points on the circumference of the HF cable.

The optical fiber 4 can be laid in a spiral shape around the insulation 2 before the outer conductor 3 is formed, as shown in Fig. 2. It lies against the surface of the insulation 2. This also applies if the optical fiber 4 is applied to the insulation 2 in an uneven, for example wavy, course as shown in Fig. 3. In both cases, the outer conductor 3 presses the optical fiber 4 at least partially into the surface of the insulation 2 when it is formed into a tube. This happens both when a smooth outer conductor 3 is pulled down and when a corrugation is pressed into it.

The optical fiber 4 can be mounted in a protective tube 5 made of a suitable plastic according to Fig. 4. According to Fig. 5, several optical fibers 4 can also be combined next to one another in the form of a band 6.

Claims (5)

Protection claims 1. Coaxial high-frequency cable with an inner conductor, with a tubular outer conductor arranged coaxially and at a distance from the inner conductor, and with an insulation made of foamed plastic which fills the space between the two conductors and serves as a spacer, in which at least one optical waveguide running over the entire length of the high-frequency cable is arranged in the outer region of the insulation, characterized in that the optical waveguide (4) rests on the surface of the insulation (2) and is at least partially pressed into the correspondingly deformable material thereof. 2. Cable according to claim 1, characterized in that the optical waveguide (4) runs helically around the insulation (2). 3. Cable according to claim 1, characterized in that the optical waveguide (4) with a non-rectilinear course runs essentially in the longitudinal direction of the high-frequency cable. 4. Cable according to one of claims 1 to 3, characterized in that the optical waveguide (4) is arranged in a protective tube (5) made of plastic. 5. Cable according to one of claims 1 to 4, characterized in that several optical waveguides (4) lying next to one another and combined in the form of a band (6) are used.