DE3900152C1 - Method for conveying a cable out of a protective tube - Google Patents

Abstract

A swelling (VD) is provided on the near cable end (NCA) in such a way as not to close the entire inside cross-section of the protective tube (SR). The protective tube is pressurised by the connection of a pressing device (PQ) which delivers a flowing medium (SM). The flowing medium exerts a thrusting pressure on the swelling (VD), and produces a corrugation (CAW1, CAW2) of the cable (CA). The medium flowing away via the swelling engages in the region of the corrugations (CAW1, CAW2) and thus produces an additional force for further transporting the cable. <IMAGE>

Description

The invention relates to a method for conveying a Cable from a protective tube through a high-pressure flowing Medium.

From GB 21 57 019 A it is known to have an optical cable move into a protective tube or the like that the first straight optical cables through a deformation device is passed in which there is a permanent wavy structure. As a permanent one deformed cable, it is then inserted into a protective tube, in which at the same end a flowing medium, e.g. B. Air or water, is injected. By attacking the pouring Medium on the permanently deformed wavy walls of the optical cable, the cable becomes the rhythm of the turbulent Flow is lifted from the pipe wall, which increases the friction reduced and the further transport is favored. However, the cable must be used in this procedure with permanent deformations to it reliably pull into the protective tube with the flowing medium to be able to.

From DE-PS 32 20 286 it is known for very long cable lengths make the drawing in with compressed air in such a way that the installation section is divided into several installation sections being, the cable over several such sections is drawn in continuously. Are on the cable itself both at the beginning and in areas further back Pull plugs are provided for each laying section one. These pull plugs close together with the cable cross-section the entire inner opening of the protective tube.

In addition to the pull-in procedure for cables in Protection tubes, however, often also have the problem of a remove existing cable from a protective tube, e.g. B. when reinstalling another transmission link. The object of the present invention is a method for conveying a cable out of a protective tube create that can be done in a simple manner and is generally applicable. According to the invention, this object solved by attaching a thickening at the near end of the cable is that only a part of the clear cross section of the Protection tube closes that by the flowing medium of at the front a pushing pressure on the thickening and thus on exercised the cable and thereby consciously as a result of compression of the cable a curl is generated in this and that the predominant Part of the flowing medium past the thickening flows towards the far end of the cable and through the cable the wave progress is further transported.

In the invention it is therefore not necessary to use the cable to impress a permanent undulating deformation (which is the case with Blowing out would not be possible anyway since the cable is already there was previously laid in a straight line), but it is sufficient that it becomes a by the pressure force on the thickening temporary waveform of the cable is coming. On this waveform of the cable then grips the flowing over the thickening Medium and additionally transports the cable, the waveforms always being due to the force on the thickening be continuously generated and maintained again. Through the Invention, it is thus possible in a particularly simple and reliable Way the cables out of protective tubes to accomplish.

In favorable cases, it can be enough to cut the butt End of the cable itself to use the end somewhat push. The invention accordingly relates to a cable type mentioned, which is characterized in that the near end of the cable is bluntly cut off and the cable only  closes part of the clear cross section of the protective tube, that a pushing through the flowing medium from the front Pressure exerted on the bluntly cut cable end and therefore deliberately a curl due to compression of the cable is generated in this and that the predominant part of the flowing Medium past the bluntly cut cable end flows towards the far end of the cable and through the cable the wave progress is further transported.

Developments of the invention are given in the subclaims.

The invention and its developments are explained in more detail below with reference to a drawing, in which part of a protective tube containing a cable is shown in cross section. The protective tube SR with the inner diameter Dr contains a cable CA which, in the present example, is to be conveyed out of the protective tube SR from left to right. For this purpose, a press device PQ is provided, which inputs a flowing medium SM via a connecting line VL into a press connector PS , which closes the left end of the protective tube SR shown in a pressure-tight manner. The flowing medium SM thus moves from left to right through the opening in the protective tube SR and thereby meets the cable CA. At the near end NCA of this cable, a thickening VD is attached, e.g. B. in the form of an annular flange, a shrunk on thickening or the like, which has an outer diameter Dv , which is between 0% and 40% larger than the outer diameter Dc of the cable CA. It is assumed that the inner pipe diameter is Dr <3 Dc . By the impact of the flowing medium SM on the thickening VD , a small longitudinal thrust is exerted on the cable end NCA , whereby this is converted from its original, ie essentially straight basic structure into a wave form, the waves in the present example with CAW 1 , CAW 2 and CAW 3 are designated. Since the thickening VD does not fill the entire clear width of the inner diameter Dr of the protective tube SR , the flowing medium SM also passes over the thickening VD into the right part and flows in the direction of the far end of the cable FCA ( not shown here). As a result of the wave structure CAW 1 , CAW 2 and CAW 3 of the cable, there is an additional possibility of attack for the flowing medium SM , which results in additional axial forces being exerted on the cable in the area of these corrugations, so that the cable is transported out of the Protection tube SR is made considerably easier. The near cable end NCA is cut smooth in the area of the thickening VD .

The thrust force exerted by the flowing medium SM in the area of the thickening VD should be selected between 0.1 N and 1 N. It is assumed that the cable CA is an optical fiber cable, ie a relatively light cable with an outer diameter in the order of 8 to 20 mm.

Since the thickening VD together with the cable CA enclosed by it must not fill the approximately clear cross-section of the protective tube SR in order to ensure that the medium continues to flow in the direction of the distant cable end FCA , the thickening VD together with the cable CA should only be between 5% and 20 Seal% of the total cross-sectional area of the free interior of the protective tube SR . At least 90% of the total cross-sectional area should preferably be kept free for the flow of the medium.

In some cases, the smooth (blunt) cable end is sufficient, ie the VD thickening can be omitted.

It is expedient if the cable diameter Dc is chosen to be less than Dr / 3 because this ensures that the flow speed and distribution are not significantly influenced by the cable.

Air can preferably be used as the flowing medium, but also one Liquid, e.g. B. water can be used.

To calculate: the flow velocity in a smooth Pipe without taking compressibility into account:

in which

Δ p is the pressure acting on length l ;
Dr the inside pipe diameter (m);
Δ l the considered partial length (m);
ρ the density of the flowing medium at the respective pressure

λ is a dimensionless resistance number, depending on the pipe roughness, e.g. B. 2 · 10 ^-2

mean.

The weight and surface of the cable play a secondary role in the transport process, but the flow cross-section through the cable should not be significantly reduced (e.g. 10%); ie the cable diameter Dc should be ≦ DR / 3.

The above equation applies in principle to air and water, whereby the expansion of the air with decreasing absolute pressure in the pipe has little effect on the practical result. The density increases proportionally with increasing pressure, v ² · ρ is little changed.

One takes this as the highest possible transport pressure 20 bar≈2 · 10⁶ N / m², a final transport speed would have to be in air of at least 35 m / s, in the Waser (because of the round 700 times the density) of at least 1.3 m / s, around the Maintain the dynamic insertion process described above to be able to.

This results (without cable) with 2 km pipe length in air and Water a required inner pipe diameter of approx. 0.02 m. In In both cases there is total turbulence. At 20 km you can with the same pressure only about ½ of the flow rate achieve or it would have to achieve the same flow rate about 10 times the inner pipe diameter available stand, which is not realistic. For very long distances does not become dynamic with air or water Shooting process be feasible.  

Here it is recommended that the cable start with a slightly sliding To provide pistons and, if necessary, at larger intervals piston with less thrust, i.e. diameter to attach. The medium should be used to increase buoyancy Water can be used. Even at water speeds of about 0.4 m / s there are still reasonable retraction speeds conditions. Prerequisites are straight lines that also pulling out again (possibly with flow support) allow. Noteworthy curvatures should be avoided.

Claims (7)

1. A method for conveying a cable (CA) out of a protective tube (SR) characterized by a medium (SM) flowing at high pressure ,
that a thickening (VD) is attached to the near cable end (NCA) , which closes only part of the clear cross-section of the protective tube (SR) ,
that from the front a pushing pressure is exerted by the flowing medium (SM) on the thickening (VD) and thus on the cable and thereby deliberately a curl is generated in the cable as a result of compression of the cable (CA) and
that the major part of the flowing medium flows past the thickening (VD) in the direction of the far cable end (FCA) and the cable (CA) is further transported through the wave progress (AW 1 , AW 2 ). 2. A method for conveying a cable out of a protective tube according to claim 1, characterized in that the near cable end (NCA) is cut smooth before the thickening (VD) . 3. A method for conveying a cable out of a protective tube according to one of the preceding claims, characterized in that the thrust force on the thickening (VD) is selected between 0.1 N and 1 N. 4. A method for conveying a cable out of a protective tube according to one of the preceding claims, characterized in that outside the thickening (VD) together with the cable (CA) between 80% and 95% of the total cross-sectional area of the protective tube (SR) for the further flow of the medium ( SM) are kept free. 5. A method for conveying a cable out of a protective tube according to one of the preceding claims, characterized in that the inner tube diameter (Dr) of the protective tube (SR) is at least three times the outer diameter (Dc) of the cable (CA) . 6. A method for conveying a cable (CA) out of a protective tube (SR) through a medium flowing at high pressure (SM) , characterized in that the near cable end (NCA) is cut off bluntly and the cable (CA) is only a part of the closes clear cross-section of the protective tube (SR) ,
that from the front a pushing pressure is exerted on the bluntly cut cable end by the flowing medium (SM) and thus a corrugation is deliberately generated in it as a result of compression of the cable (CA) and
that the majority of the flowing medium flows past the bluntly cut cable end (NA) in the direction of the far cable end (FCA) and the cable (CA) is further transported by the wave progress (AW 1 , AW 2 ). 7. The method according to any one of the preceding claims, characterized in that the outer diameter in the region of the cable end (NCA) is chosen between 0% and 40% larger than the outer diameter (Dc) of the cable (CA) .