WO1998042925A1 - Cable to protect piping from the effects of frost - Google Patents

Abstract

Disclosed is a cable intended for use in piping carrying aqueous liquids to guard against frost and its effects. Said cable is comprised of heating electric conductors (20), which are combined with compressible and elastic materials (10) in order to offset the expansion due to the freezing of the liquid. The compressible heating cable is inserted into the piping to be protected.

Description

Cable to protect pipes against the effects of frost.

The object of the present invention is to prevent the rupture of pipes in the event of freezing of the internal liquid.

The freezing of an aqueous liquid results in an expansion of

10% by volume, but the elastic limit of metals corresponds to an expansion of less than 1%. The freezing of water in a pipe therefore exceeds 10 times the elastic limit of metal, the latter being forced to expand by 10 %.

Materials like cast iron or concrete have even lower elastic limits.

Synthetic materials have various properties which often evolve with aging.

Same remarks for the devices mounted on the pipes: valves, fitting, ...

The danger of freezing is especially important when there is no flow in the pipeline. The volume of trapped liquid, equal to that of the pipe, expands overall or by portion of pipe between gel plugs.

Currently, the means used are of 2 types:

- heating of pipelines by electrical equipment covering the pipeline. - introduction of compressible materials inside the pipeline or allowing the evacuation of the excess liquid during the gel establishment phase.

- use of transverse or longitudinal expansion means: valve, expansion vessel, expansion connection ... The disadvantage of heating systems is that they are not 100% safe in the event of an electrical failure or deterioration of conductors over time, and their use is only possible if a source of electric current is possible. Solutions with evacuation of excess liquid by an internal pipe do not protect long lengths because the longitudinal transfer of liquid is not more possible if trapped between 2 points that froze first in time. In addition, the overall expansion is only compensated by the compression of the wall of the pipe, which is insufficient. The use of compressible materials used inside the pipeline has the drawback of having doubtful behavior over time as a result of the progressive degradation of organic materials over time and successive compressions. The use of expansion means is expensive and these must be repeated frequently throughout the pipeline. This drawback is even more important for the means of longitudinal expansion. The purpose of the present invention is to define the combination of means which guarantee safety close to the absolute, regardless of the scenarios: breakdowns, accidents, etc. In order to overcome the different scenarios, the invention consists in combining different means, the effects of which add to or take over from one another in the event of failure due to breakdown or deterioration over time. Several combinations are possible depending on the use case: electrical source or not, new or existing installations, types of pipes, etc. The combinations according to the invention use the following means or methods, some of which, in certain variants, are already known:

1- use of compressible materials inside

2- heating by internal conductors in the pipeline MEAN 1: compressible materials inside: This means can be achieved by the introduction of a coil of compressible materials.

The devices can be protected according to the same principle. The geometric shape used can constitute a recessed patch or any other geometric shape. The volume of the compressible material which must absorb compression of 10% of the liquid must have a section of approximately 15% according to its possible rate of compression, which gives a diameter of 40% of that of the pipe if its section is cylindrical.

This means does not prevent freezing of the pipe and the longitudinal transfer of liquid is limited. MEDIUM 2: heating by internal conductors:

The introduction of 2 inner conductors, having a certain electrical resistance, makes it possible to heat the liquid, either to prevent it from freezing, or to allow a longitudinal transfer during the expansion phase at the start of the gel process. (one of the 2 conductors can be formed by the pipe itself if it is metallic. This facilitates the electrical "passage" of obstacles: valves.) In the event of very low temperatures, the power and the necessary voltages can be difficult to use if you want to prevent freezing permanently. In all cases, a moderate voltage (less than 50 volts) will ensure the longitudinal transfer of liquid during the setting phase of the gel. This means alone does not therefore provide absolute protection easily.

The means for connecting the cables with one exterior, through the walls of the pipeline, are known. COMBINATION 1 + 2: the electrical conductors are embedded in a compressible material: One of the combinations of the invention is to use electrical cables, the coating material of which is composed of materials based on rubber or flexible plastic foams, the compositions are known. One possible form is the use of coaxial cables (see television antenna cable) with a cylindrical braid and an inner cable. The advantage of the cylindrical braid is to mechanically maintain the compressible material and to ensure the latter a better resistance over time. Maintaining an electrical voltage also allows it to remain within a temperature range in which it retains optimum elasticity characteristics (hence greater longevity) and to maintain for a certain time a longitudinal transfer of the internal liquid. See figure 1.

The surface braid also has the advantage of good heat diffusion. The resistivity allowing the diffusion of heat must be concentrated on this conductor.

Figure 2 shows a variant for the arrangement of conductors.

In the event of very low temperatures, it is no longer essential to provide significant heating (therefore an intensity), difficult to implement in order to guarantee 100% safety and electrical insulation in the event of high voltages. The compression of the material takes over for protection against overpressure.

To ensure the current loop, the 2 conductors will be joined at the end of the cable without requiring an external connection device or connected to 2 terminals of a valve to ensure its heating and / or the relay for the rest of the pipeline.

Optionally, a pressure detector can adapt the electrical power according to the pressure in the pipeline, the latter increasing in proportion to the amount of partial gel already formed inside.

As a variant, the invention consists in using a compressible material containing conductive particles and whose electrical resistance is inversely proportional to the compression, which makes it possible to automatically adapt

1 current intensity depending on the gel and this in the locations concerned with a reduced voltage.

This property allows, optionally, the detection of frost by measuring the variation of the electrical resistance.

In the absence of gel, the intensity of the current will be zero or close to zero.

Laying a compressible cable is relatively easy, even for existing installations. Safety is ensured even in the event of a power cut, unlike heating systems alone.

CABLE RANGES: for a diameter pipe: D, the diameter of the compressible cable should be: d = about 0.4 D for 100% compression, which will not be useful in all cases, in particular if the material of the pipe has a high coefficient of elasticity. To ensure a constant heating power per unit of section of the cable (for a given voltage and resistivity), the equivalent diameter of the conductors: de must be fixed by the following formula: dc * dc = K * D * L * L, L being the length to protect. The cable ranges: external diameters and conductive sections, will therefore be established according to the 3 parameters: K: degree of protection sought, D: diameter of the pipe, L: length to be protected. The range could be reduced by the possibility of using several compressible heating cables in parallel, associated with only compressible cables. The slowness of the freezing process and the possibility of longitudinal liquid transfer allow a large approximation in the choice of cables from a reduced range, in particular for the heating powers. Standardization could also be facilitated by the use of several electrical voltages.

FIG. 1 represents a cable with a central conductor 10 and a concentric conductive braid 25 which includes an elastic and compressible material 10, of the plastic foam type containing air bubbles. An outer sheath 15 provides electrical insulation with respect to the pipe 5.

FIG. 2 represents a cable with several conductors 25 wound in a spiral around a flexible tube containing air 10 and protected by a sheath 15.

The different conductor connections allow the electrical resistance to be adapted to the desired length and power. For long-term security, the air may be enclosed in pockets of reduced length so that local deterioration does not affect the entire length of the cable. The air can be replaced by another material compressible.

All the pipes for transporting aqueous liquids can be protected by the cables of the present invention, when they are subjected to frost stresses. The same cables can also be used to heat the interior of pipes carrying non-aqueous liquids, in order to fluidize them. In this case, the cable material will not necessarily be compressible. For containers to be protected, the same cables can be used, by introducing a length proportional to the volume of the liquid and to the exchange surfaces with the exterior.

Claims

1- device preventing the rupture of a pipe in the event of frost, characterized in that it consists of a cable constructed by combining electrical heating elements and elements made of compressible and elastic materials, the said device being introduced into the pipeline to be protected. 2- device according to claim 1, characterized in that the heating elements consist of several electrical conductors.

3- device according to claim 1, characterized in that the conductors are concentric with the compressible materials.

4- device according to claims 1 and 3, characterized in that the heating elements consist of a coaxial cable whose internal conductor is surrounded by a metallic conductive cylindrical braid enclosing the compressible materials.

5- device according to claim 1, characterized in that the heating conductors are placed next to the compressible materials.

6- device according to one of the preceding claims, characterized in that one of the conductors is formed by the pipe itself, the latter being metallic.

7- device according to claim 1 characterized in that the compressible material contains particles or conductive fibers. 8- device according to claim 1 characterized in that the plastic material encloses compressible gas.