FR2748545A1 - Thermal isolated conduit for transfer of liquid natural gas - Google Patents

Abstract

The thermal isolating pipe has two coaxial tubes (12,14), each being made from tube sections (121,122...141,142...) end to end connected. The space between the two tubes is filled of a thermal isolating material (22). The internal tube is made of a material with a low coefficient of contraction, chosen from materials so that the product of coefficient of contraction for Youngs Modulus of the material should be less than 1.5 MPa/deg.K for the temperature range of -160deg.C to +20deg.C. The internal (14) tube's thickness is less than 6mm, and the external (12) tube's thickness, which is made of steel, is greater than 10mm. The thermal isolating material (22) has a coefficient of conduction of less than 0.02 W/m.deg.K. Centring rings (20) are placed regularly along the length of the pipe to keep the tubes concentric.

Description

THERMALLY INSULATED CONDUIT FOR GAS TRANSPORT
NATURAL LIQUEFIED.

The present invention relates to a pipe for the transport of fluids at cryogenic temperatures, and in particular for the transport of liquefied natural gas or
LNG, on land and underwater.

 We know that to be able to be transported, natural gas is liquefied, after its extraction from the ground. This operation is carried out at a temperature of around - 161 "C in a liquefaction plant. The natural gas is then loaded into LNG carriers which transport it to a regasification plant. Transport between said plants and LNG carriers in highly insulating pipes which limit thermal losses and therefore the vaporization of LNG.

 Patent No. 2,673,264 discloses a pipe for transporting hydrocarbons comprising an outer tube and an inner tube both made of steel, mounted coaxially, the space between the two tubes or annular being filled with a material thermally insulating. The transport line is produced by welding end to end sections of internal tubes and connecting sections of external tubes by means of threaded sleeves.

 To carry out the laying of such a pipe, the internal tubes are welded and the external tubes are assembled by means of the sleeves, these operations being carried out on a barge, then the pipe is dragged, as it is assembled, along an inclined ramp attached to the back of the barge. This ramp allows the pipe to slide in the water while maintaining traction on the end. The pipe comes to rest on the seabed according to an S-profile.

 During operation, the temperature gradient between the hydrocarbons and the surrounding environment induces very significant expansion efforts which require the use of mechanical recovery parts or tulips which also have the function of ensuring compartmentalized sealing of the annular.

 However, in the application to LNG transport, the use of such tulips is not desirable because they constitute thermal bridges which locally lower the temperature of the external tube (cold point).

 In addition, the thick internal tube used for transporting hydrocarbons is unsuitable in the case of LNG application, since in the latter case the pressure of the effluent is low and corrosion is practically nothing.

 Finally, the insulation used in these hydrocarbon transport pipes does not necessarily offer the best performance at the cryogenic temperatures concerned by the present invention.

 The present invention aims to provide a pipe with concentric tubes for the transport of fluids at cryogenic temperatures, in which the heat losses are reduced to a minimum and the thermal bridges are eliminated.

To this end, the subject of the invention is a pipe of the type comprising two coaxial tubes, one external and the other internal, each of these tubes being formed of sections of tubes connected end to end and the tubular space between both tubes being filled with thermal insulation, characterized in that
- the internal tube is made of a material with a low coefficient of expansion, chosen from materials such that the product of the coefficient of expansion by the Young's modulus of said material is less than 1.5 MPa / OK for temperatures between - 1600C and + 200C,
- the inner tube has a wall thickness of less than 6 mm,
- the outer tube is made of steel and has a wall thickness greater than 10 mm, and
- the thermal insulator has a thermal conductivity less than 0.02 W / m.OK.

 According to a particular embodiment, the internal tube is made of Invar.

 The inner tube is held in a concentric position in the outer tube by any suitable means, for example by means of rigid centralizers made of insulating material. The insulating material forming the centralizers has an equivalent thermal conductivity of less than 0.6 W / m.OK.

 The pipe according to the invention has very low heat losses, due to the specific insulation used, the elimination of thermal bridges at the connection areas between the sections of tubes and also because the centralizers in insulating material n '' evacuate practically no heat.

 In addition, the reduction in thickness of the inner tube reduces its weight and therefore its thermal inertia, which leads to a gain in efficiency when the line is put into service. The compression forces which are taken up by the centralizers are also reduced, which widens the range of choice of the material of the centralizers.

 In addition, the sealing of the pipe is excellent since the external and internal tubes are welded and no longer connected by means of sleeves as in the prior art. The insulation is therefore protected against sea water and its performance will remain unchanged over time. The risk of corrosion of the inner tube by seawater is completely eliminated.

 An embodiment of the invention will now be described with reference to the single appended figure which represents an axial section view of a pipe section according to the invention.

 The pipe 10 shown in the figure comprises an outer tube 12 and an inner tube 14 with a common axis x-x. The inner tube carries liquefied natural gas at -1610C. It is made of a material with a low coefficient of expansion. The materials which are suitable for the internal tube are chosen so that the product of the coefficient of expansion by the Young's modulus of the material is less than 1.5 MPa / OK. Invar fulfills this condition.

 The inner tube has a wall thickness of less than 6 mm. Because of these characteristics, the inner tube has a low thermal inertia and quickly warms up to the temperature of the LNG being transported.

 The outer tube is much more resistant because it must provide mechanical protection for the pipe. It is made of steel and has a relatively greater thickness, for example greater than 10 mm for a diameter of the order of 760 mm.

 The tubes 12 and 14 are produced respectively by butt welding of tube sections 121, 122, ... and 141, 142, ... by weld beads 16, 18.

 The inner tube 14 is held in a concentric position relative to the outer tube 12 by any suitable means, for example by means of centralizers 20, made of insulating material so as to avoid thermal bridges. In the embodiment illustrated in the figure, the centralizers are constituted by rigid annular discs made of insulating material. The centralizers are close enough to avoid the formation on the internal tube of an excessive arrow between successive centralizers. However, the number of centralizers will be reduced as much as possible in order to limit heat losses.

By way of example, the characteristics of a line for the transport of liquefied methane having the following dimensions will be given.
Line length 5000 m
Internal tube diameter 616 mm (24 inches)
Outer tube diameter 760 mm (30 inches)
Internal tube thickness 3 mm
Thickness of the outer tube 15 mm
Distance between centralizers 10 m.

 With these data, an arrow between consecutive centralizers of 1.5 mm is obtained.

 Taking into account the dimensions of the internal tube and the density of the effluent (600 kg / m3), the weight that the centralizers must take up is of the order of 250 kg / m. Centralizers using conventional insulation can easily take on this load.

 The annular is filled with an appropriate thermal insulator 22, adapted to the temperature of the LNG. The choice of this insulator results from the admissible heat exchange coefficient of the line which itself depends on the admissible evaporation rate.

This coefficient can be calculated in the case of the aforementioned line, taking into account that when the inner tube is cooled, a vapor plug is created. Suppose that the liquid and vapor mass flow rates are 300 kg / s and 25 kg / s respectively, that the inlet pressure is 5 bars and that the outlet pressure is 4 bars (therefore A p = 1 bar) . From the gas flow rate, the temperature drop-down time is calculated, ie 27 min, and from the liquid flow rate, the admissible heat exchange coefficient U, or U = 0.36 W / m2, is calculated. K. We deduce the heat flux per linear meter, or 110 W / m. This heat flow breaks down into 100 W / m in the insulation and 10 W by the centralizers. A flux of 100 W / m corresponds to a thermal conductivity of the insulation of 0.017 W / m.OK. This conductivity corresponding to a category of existing insulating materials. Insulators based on silica under a controlled industrial vacuum (10 to 100 mbar) provide the best thermal insulation at cryogenic temperatures. Other insulators may be suitable depending on the permissible evaporation rate.

 The pipe submerged in the sea is generally unstable. To immobilize it, we sometimes ballast it, for example by coating it with a layer of concrete 24.

Claims (6)

 1. Thermally insulated pipe for the transport of liquefied natural gas, of the type comprising two coaxial tubes, one external (12) and the other internal (14), each of these tubes being formed of sections of tubes (121, 122 ... 141, 142 ...) connected end to end and the tubular space between the two tubes being filled with thermal insulation (22), characterized in that  - the internal tube (14) is made of a material with a low coefficient of expansion, chosen from materials such that the product of the coefficient of expansion by the Young's modulus of said material is less than 1.5 MPa / OK for temperatures between - 1600C and + 200C,  the internal tube (14) has a wall thickness of less than 6 mm,  the external tube (12) is made of steel and has a wall thickness greater than 10 mm, and  - the thermal insulator (22) has a thermal conductivity less than 0.02 W / m.OK.  2. Pipe according to claim 1, characterized in that the internal tube is made of Invar.  3. Pipe according to claim 1, characterized in that the inner tube is held in a concentric position relative to the outer tube by centralizers (20) constituted by rigid annular discs of insulating material mounted at regular intervals along the pipe .  4. Pipe according to claim 3, characterized in that the insulating material constituting the centralizers has an equivalent thermal conductivity coefficient of less than 0.6 W / mOK.  5. Pipe according to claim 1, characterized in that the thermal insulator (22) is based on silica.  6. Pipe according to one of claims 1 and 5, characterized in that the annular space occupied by the thermal insulator (22) is placed under controlled industrial vacuum.