BE1025756B1 - FLEXIBLE AND THERMAL INSULATING COAT - Google Patents

Abstract

A flexible and thermal insulating jacket comprises a flexible carrier to which a plurality of thermally insulating strips are attached. Each of the strips, which comprise a mixture comprising thermally insulating particles, has • two main surfaces that have the shape of a rectangle, triangle or trapezium, • two end surfaces and • two side surfaces. The cross-section of each of the strips along a plane perpendicular to their main planes and perpendicular to the longitudinal direction has a geometric shape selected from the group of rectangles, trapeziums and trapeziums with the truncated corners between the oblique sides and the longest side, the adjacent the mutually side of each two strips positioned next to each other are substantially parallel and are separated from each other at the level of the attachment to the flexible support, and wherein the thermally insulating particles are aerogel particles, pyrogenic metal oxide particles or a combination of both.

Description

FLEXIBLE AND THERMAL INSULATING COAT

Technical area

The present invention relates to flexible and thermally insulating sheaths, in particular sheaths comprising a mixture comprising thermally insulating particles. The invention also relates to methods for thermally insulating curved, for example cylindrical or conical objects with such jackets.

State of the art

Flexible and thermal insulating jackets for thermally insulating cylindrical or conical objects are known. An example of such a jacket is the product MICROTHERM® SLATTED - 1000R from Microtherm NV (Sint Niklaas, Belgium).

Summary of the invention

It is an object of the invention to provide flexible and thermal insulating jackets, which are easy to manufacture in different dimensions, suitable for thermally insulating cylindrical or conical objects with different diameters.

One or more of the above objectives and / or advantages is achieved by flexible and thermal insulating jackets according to the present invention.

According to a first aspect of the invention, a flexible and thermally insulating jacket is provided, which jacket suitable for coating the inner and / or outer surface of curved object. The jacket comprises a flexible carrier on which there are several thermally insulating strips

BE2017 / 5903

2017/5903 attached. Each of the strips, each strip comprising a mixture comprising thermally insulating particles, has • two main surfaces that have the shape of a rectangle, triangle or trapezium, • two end surfaces and • two side surfaces that connect the two main surfaces with each other in the longitudinal direction.

The cross-section of each of the strips along a plane perpendicular to their main planes and perpendicular to the longitudinal direction is a geometric shape selected from the group of rectangles, trapeziums and trapeziums with the truncated corners between the oblique sides and the longest side and with the corners of these geometric shapes. The adjacent sides of each two adjacent strips are substantially parallel and separated from each other at the level of the attachment to the flexible support. The thermally insulating particles are airgel particles, pyrogenic metal oxide particles or a combination of both.

The flexible and thermal insulating jackets can be particularly suitable for coating a cylindrical or conical inner and / or outer surface of object.

According to embodiments of the present invention, the cross-section of each of the strips may be a geometric shape selected from the group of rectangles, symmetrical trapeziums and symmetrical trapeziums with the truncated angles between the oblique lines along a plane perpendicular to their main planes and perpendicular to the longitudinal direction. sides and the longest side, which shape is symmetrical with respect to a longitudinal direction. The corners can always be rounded. The radius of the rounding can vary from 0 mm (no rounding) to half the average thickness of the strip. The sector around which the corners are rounded can vary between 0 ° (no rounding) and 90 °.

BE2017 / 5903

2017/5903

BE2017 / 5903

According to embodiments of the present invention, the adjacent side of each two adjacent strips can be separated by a distance of at least 0.5 mm at the level of the attachment to the flexible carrier.

Preferably, the adjacent side of each two adjacent strips are spaced apart by a distance of at least 1 mm, optionally at least 2 mm, for example at least 3 mm or even at least 4 mm. This distance is preferably less than 100 mm, for example less than 90 mm.

The "major planes of the strip" are the planes with the largest surface area of the volume of the strip. The "side faces of the strip" are the longest of the four faces describing the volume of the strip, together with the two main faces, and are adjacent to the main faces along the boundary of the main faces in the longitudinal direction. The end faces are the end faces of the volume of the strip which together with the main faces and the side faces define the volume of the strips. The longitudinal direction of a strip is the average direction of the two side faces.

Thermal insulation means a thermal conductivity of less than 50 mW / m * K. The thermal conductivity of the strips is preferably less than 45 mW / m * K, preferably less than 30 mW / m * K. This thermal conductivity is the thermal conductivity at 300 ° C, measured according to ASTM C177.

Multiple strips means at least 2 strips, often 3, 4, 5, 6 or more strips, for example 4 to 10 strips or more.

The strips can have identical, similar or different shapes.

2017/5903

BE2017 / 5903

According to embodiments of the present invention, the strips may have substantially identical shapes.

The strips can have a different length in the longitudinal direction. The strips may be positioned and attached over the flexible supports in such a way that these strips cover part or all of the surface of the flexible support. The flexible carrier can actually have any outer circumference. The circumference can be, for example, square or rectangular, triangular, parallelogram-shaped or trapezoidal, but also an arbitrary polygon or a shape with a flowing or partially flowing circumference. The surface of the flexible support can optionally be provided with openings or incisions, which openings or incisions are not covered or bridged with or by strips.

According to embodiments of the present invention, the maximum thickness of the adjacent sides of two adjacent strips can be M, the distance between adjacent sides of two adjacent strips can be between 1 mm and M + 20 mm.

Preferably, the distance between adjacent sides of two adjacent strips is between 1 mm and M + 15 mm, such as between 1 mm and M + 10 mm.

According to embodiments of the present invention, the strips can have an average thickness of 1 mm to 80 mm. The average thickness is preferably between 1.5 mm and 70 mm, preferably between 2 mm and 60 mm. The average thickness is the average of the measured thicknesses over the whole of the main planes.

According to embodiments of the present invention, the strips may have a substantially uniform thickness. A substantially uniform thickness means that the thickness of the strip is virtually identical at every point of a main fall. With the thickness of a strip in a point of the main surface is meant the minimum distance

2017/5903

BE2017 / 5903 from this point on the first major plane to a point of the other major plane.

Strips with a substantially uniform thickness have essentially flat and almost parallel main surfaces. Optionally, the strips are provided with recesses and / or thinner places that allow the sheath to connect to projecting elements or irregularities on the surface of the mold to be wrapped.

According to embodiments of the present invention, the strips may have a length from 20 mm to 1500 mm in the longitudinal direction. This length is preferably between 50 mm and 1200 mm. Different strips can have different lengths in this direction.

According to embodiments of the present invention, the strips may have a length of 10 mm to 1500 mm in the direction transverse to the longitudinal direction and parallel to the main surfaces. This distance is preferably between 20 and 1000 mm, for example between 100 mm and 1000 mm. Different strips can have different lengths in this direction.

According to embodiments of the present invention, the flexible carrier can be a textile cloth or foil.

Suitable textile fabrics are preferably glass and / or synthetic fiber-based textile fabrics, for example glass and / or synthetic fiber fabrics or glass and / or synthetic fiber nonwovens. In a preferred embodiment, the textile cloth is a woven glass fiber cloth, for example a glass fiber cloth made of glass fibers of type E glass, S glass, silica glass, quartz glass or combinations of these fibers, which cloth may or may not be siliconized.

Suitable films can be, for example, polymeric or aluminum films. The thickness of the film is preferably between 0.01 mm and 1 mm.

2017/5903

BE2017 / 5903 6

By flexible is meant that the support can be wound around a cylindrical surface, which surface has a bending radius of 10 cm. The carrier can optionally be wound around a cylindrical surface, which surface has a bending radius of 5 cm. The carrier can optionally be wound around a cylindrical surface, which surface has a bending radius of 1 cm.

According to embodiments of the present invention, the strips may be bonded to the flexible support by means of adhesive and / or double-sided tape. The adhesive is preferably water glass (alkali silicate) based (e.g. Na water glass, K water glass, Li water glass or combinations of such water glass), phosphate based adhesive, organic adhesives. Optionally, the water glass-based adhesive comprises minerals, for example clay. Preferably, the adhesive, or the adhesive of the double-sided tape, is temperature resistant, preferably highly resistant to higher temperatures. Resistant to higher temperatures means that the adhesion does not change substantially at temperatures between room temperature and 100 ° C, between room temperature and 300 ° C. in an alternative form, fast glue is used, for example thermoplastic or thermosetting hot melt adhesives.

According to embodiments of the present invention, the shape of each of the strips can be provided by a mold-pressed mixture comprising thermally insulating particles.

According to embodiments of the present invention, the mold-pressed mixture comprising thermally insulating particles may be enveloped by a textile cloth.

According to embodiments of the present invention, the mixture comprising thermally insulating particles is first placed in a ditch consisting of textile fabric, after which the mixture is compressed in the fabric. The pressing, whether or not

2017/5903

BE2017 / 5903 not already in a demolition consisting of textile fabric, can happen in wet or dry condition. This cover can be a textile fabric stitched tight in a demolition, for example a glass or synthetic fiber fabric, for example a woven or non-woven fabric.

According to embodiments of the present invention, the geometric shape of the cross-section can have rounded corners.

According to embodiments of the present invention, the geometric shape of the cross-section can be a symmetrical or non-symmetrical trapezoid, the angle between each of the oblique sides and the large side being between 30 ° and 90 °. This slope of the sloping side is preferably between 45 and 90 °.

According to embodiments of the present invention, the strips may be adhered to the flexible support along the long side of their symmetrical trapezoidal section.

According to embodiments of the present invention, the thermally insulating particles may form part of a thermally insulating mixture comprising • 30 to 90% w thermally insulating particles;

• 1 to 50% w infrared opacifier or adsorbent;

• 0 to 30% w staple fibers;

• 0 to 30% w endothermal material;

• 0 to 20% w microsilica.

The mixture is of course preferably homogeneous in composition.

Preferably, the specific surface area of the thermally insulating particles is between 50 and 1000 m ² / g.

2017/5903

The infrared opacifier or adsorbent can be rutile (natural and / or synthetic), anatase, iron oxide, silicon carbide, carbon, graphite, zirconium and / or clay, or mixtures of these.

The staple fibers are preferably fibers from E glass, R glass, S glass, silicate fibers, alumina fibers, alkaline earth silicate fibers, aluminum silicate fibers, ceramic fibers and / or combinations of such fibers. Preferably the fibers have a length of 1 to 12 mm and a thickness of 0.1 to 15 microns.

The endothermal material can be aluminum tri hydrate (ATH), magnesium hydrate (MgOH), or gypsum, or mixtures of these.

The microsilica (also known as silica fume) preferably has a specific surface of 10 to 50 m ² / g.

Pyrogenic metal oxide particles are, for example, pyrogenic aluminum oxide or pyrogenic silicon oxide

According to embodiments of the present invention, the thermally insulating particles may comprise pyrogenic silica particles. Pyrogenic silica is also known as pyrogenic silica. In general, the English term fumed silica is used more often.

Aerogel particles can be metal oxide aerogels, for example silicon oxide (silica) aerogels, alumina aerogels, zirconia aerogels, titania aerogels, but also polymeric aerogels, or combinations thereof. Silicon oxide (silica) aerogels are preferably used.

Aerogels can be xenogels, cryogels, pyrogels.

According to embodiments of the present invention, the thermally insulating particles may comprise silicon oxide (silica) airgel particles.

BE2017 / 5903

2017/5903

BE2017 / 5903

According to embodiments of the present invention, the mixture in the strips can have a density of between 50 and 500 kg / m ³ .

The advantage of these flexible and thermal insulating jackets is that they lend themselves to the coating, possibly wrapping of curved, for example cylindrical, convex, dome-shaped or conical surfaces. When sheathing, the flexible carrier is positioned so that the flexible carrier experiences a greater bending radius than the neutral line of the jacket. If the jacket is applied on the side of the object away from the point of curvature or axis, the flexible carrier will push the strips against the surface. If the jacket is arranged on the side of the object, oriented towards the point of curvature or axis, the flexible carrier will push the strips against each other laterally. In both cases, the force exerted on the strips will cause the strips to press against the wall to be coated.

For cylindrical surfaces, the sides of the strips can all run parallel. In this case, the strips can each have two substantially pearl-like main surfaces, which have the shape of a rectangle.

The flexible and thermal insulating jacket can be bent around an axis that is parallel to the longitudinal direction of the stoves. By allowing this axis to coincide with the axis of the cylindrical object to be coated or encased (for example, a pipe or pipeline, steam pipe, gas pipe, pipe for chemical or petrochemical products, etc.), the jacket can curve around the outer wall of this article . The small distance between two adjacent strips allows the side faces of each of the strips to snap to each other, so that this curvature of the jacket does not result in the material from which the strips are made being under too great pressure or so that these materials can possibly crack, break or be damaged.

2017/5903

BE2017 / 5903

For conical surfaces, the sides of the strips cannot all run parallel. In this case, the strips will each have two quasi-pearl main surfaces, which are in the form of a rather long-stretched trapezoid.

The flexible and thermal insulating sheath can be bent around an axis that is oriented from one end face to the other end face. By allowing this axis to coincide with the axis of the cylindrical object to be coated or encased (for example, a pipe or pipeline, steam pipe, gas pipe, pipe for chemical or petrochemical products, etc.), the jacket can curve around the outer wall of this article .

For other curved surfaces, for example spherical shapes or domes, combinations of different shapes, lengths and cross-sections can be chosen.

The advantage of these products also has an advantage in producing such jackets. If jackets are to be manufactured for encasing objects with different diameters, it is simply sufficient to adhere the number of strips required to each other on a bearing surface. Thus, tailoring different jackets can easily be realized by choosing this number of strips.

Smaller widths of strips, optionally combined with an appropriate distance between the strips laterally and / or the thickness of the strips, makes the jacket suitable for larger or smaller diameters of objects to be encased.

According to a second aspect of the invention, the use of a flexible and thermal insulating sheath according to the first aspect of the invention is provided for thermally insulating the inner and / or outer surface of a curved, preferably cylindrical, spherical dome -shaped or conical object.

According to embodiments of the present invention, the article can be selected from the group consisting of tubes, cone, bends, domes and / or ovens.

2017/5903

BE2017 / 5903

These objects can form part of chimneys or outlets, tube systems, for example tube systems for transporting heated or cooled fluid, for example in the chemical or petrochemical industry, compensators, washing towers, for example gas washing towers, or channels for guiding hot liquid flows, for example molten flows glass, as well as so-called "feeder bowls", being the end piece of a channel for guiding molten glass, where the glass blobs are formed which are then transformed into glass objects, for example bottles.

According to embodiments of the present invention, the flexible and thermal insulating jacket can be used to coat a portion of the inner surface of a furnace wall.

The independent and dependent claims represent specific and preferred features of the embodiments of the invention. Characteristics of the dependent claims can be combined with characteristics of the independent and dependent claims, and this in any suitable manner as would be clear to a person skilled in the art.

The above-mentioned and other features, properties and advantages of the present invention will be clarified with the aid of the following examples of embodiments, optionally in combination with the drawings. The description of these exemplary embodiments is given for clarification, without the intention of limiting the scope of the invention. The reference numerals in the following description refer to the drawings.

Brief description of the figures

2017/5903

BE2017 / 5903

Figure 1 is a schematic representation of a top view of embodiment of a flexible and thermal insulating jacket according to the invention.

Figure 2 is a schematic representation of part of the cross-section of this jacket in Figure 1, along the plane AA ".

Figure 3 is a schematic representation of a detail of the strips, part of a flexible and thermal insulating jacket according to the invention.

Figure 4 is a schematic representation of part of a cross-section of an alternative sheath along the plane AA ".

Figure 5 is a schematic representation of a jacket according to the invention, which is wrapped around a cylindrical object.

Figures 6a to 6g are schematic representations of jackets according to the invention.

Figures 7a and 7b show a schematic representation of a jacket according to the invention, which was used to coat the inside of a cylindrical oven.

The same reference numerals refer to identical, similar or analogous elements in the other figures. The figures are schematic and not drawn to scale.

Description of examples of embodiments

The present invention is described below using specific embodiments.

It should be noted that the term "comprising", as used for example in the claims, may not be interpreted in a limiting sense, limiting to the following elements, features and / or steps. The term "comprising" does not exclude the presence of other elements, features or steps.

So the scope of an expression "an object comprising the elements A and B" is not limited to an object that only contains the elements A and B.

2017/5903

BE2017 / 5903

The scope of an expression "a method comprising steps A and B" is not limited to a method that only contains steps A and B.

In the light of the present invention, these terms only mean that the relevant elements or steps for the invention are the elements or steps A and B, respectively.

In the following specification, reference is made to "an embodiment" or "the embodiment". Such a reference means that a specific element or feature described with reference to this embodiment is included in at least this one embodiment.

However, the occurrence of the terms "in one embodiment" or "in one embodiment" at different places in this description does not necessarily refer to the same embodiment, although it may refer to the same embodiment.

Furthermore, the features or characteristics may be combined in any suitable manner in one or more embodiments, as would be apparent to those skilled in the art.

A top view of an embodiment of a flexible and thermal insulating jacket according to the invention is shown in figure 1. Figure 2 shows a part of the cross-section of this jacket along the plane AA '.

A flexible and thermally insulating sheath 1 comprises a flexible carrier 10 to which thermally insulating and essentially flat strips 20 are attached. In this embodiment, each of the strips 20 has two substantially parallel major planes 22 and 24 which have the shape of a rectangle, which shape is symmetrical with respect to a longitudinal direction 30. The longitudinal direction of the strips are parallel. Each of the strips 20 also has two end faces 42 and 44 and two side faces 52 and 54.

2017/5903

BE2017 / 5903

The cross-section of the casing along the plane AA ', perpendicular to the main planes and 24 and perpendicular to the longitudinal direction 30 is shown in Figure 2. The cross-section of each of the strips 20 according to AA' is a geometric shape selected from the group of rectangles, symmetrical trapezoidal and symmetrical trapezoidal with the truncated corners between the sloping sides and the longest side. In this embodiment this is a rectangular shape 60 with rounded corners 61. The rounding of the corner is half the thickness of the strip, and this through 90 °. 84 indicates the stitching of a textile cloth, in this case a glass fiber cloth in the form of a scrapping, which was filled with fumed silica after which this combination was pressed into the strip itself.

As visible in Figures 1 and 2, the adjacent sides 70 and 71 of each of two adjacent strips 200 and 210 are substantially parallel. At the level of the attachment to the flexible carrier, the adjacent sides 70 and 71 are separated by a distance D of 1 mm. Each strip has a thickness H of 18 mm, a length L of 520 mm and a width B of 119 mm.

In an alternative embodiment, where the sheath is suitable for wrapping a conical object, the two substantially parallel major planes have a symmetrical trapezoidal shape. Here too, the adjacent sides of each two strips positioned next to each other will lie substantially parallel and at a similar small distance from each other. The longitudinal direction of the strips do not run parallel, but rather, radially from an imaginary central point.

Each strip 20 is a strip as shown in Figure 3. A pressed volume 80 comprises a mixture comprising thermally insulating particles, in this embodiment pyrogenic silica, with specific surface area of the thermally insulating particles between 50 and 1000 m ² / g. As further additives, opacifying particles and glass fibers were added in this pressed volume 80

2017/5903

BE2017 / 5903 added. All products to be pressed are filled in a demolition made from stitched glass fiber cloth 82. The stitching is indicated by 84. The glass fiber cloth is made from glass fibers of type E glass, S glass, silica glass, quartz glass or combinations of these fibers. In a preferred embodiment, an E-glass fiber woven fabric is used. The products are pressed together with the textile cloth in the form of the beam-shaped strip. Pressing is carried out to a density of 140 to 500 kg / m ³ , preferably to a density of 220 to 300 kg / m ³ .

The strips have a thermal conductivity of less than 33 mW / mK. According to various embodiments, the average thickness of the strips is between 3 and 50 mm.

By means of an adhesive 90 based for example on water glass (more particularly Na water glass or Sodium silicate), the strips 20 are glued side by side and with a mutual distance of about 1 mm on a flexible support 10, being a woven glass fiber cloth made of type E glass fibers. glass, S glass, silica glass, quartz glass or combinations of these fibers, which cloth may or may not be siliconized. Preferably the same cloth is used as the cloth used to make the strips.

In this embodiment, all strips are of the same length and width. In an alternative embodiment, strips may differ in length and / or width relative to each other. Also in this embodiment all pairs of strips are separated from each other at the same distance. In an alternative embodiment, the separation between each pair of strips may differ. These features allow you to match the jacket with more complex curved surfaces.

An alternative to the glue is the use of a double-sided tape. This tape can coincide longitudinally with each of the strips and be applied to the side of the strip to be attached, after which the strip is applied to the flexible carrier. This tape can also be used in the longitudinal direction

2017/5903 coincide with each of the strips and are applied to the flexible carrier, after which the side to be attached to the strip is brought against the tape. This tape can also be applied to the flexible support in the transverse direction with respect to each of the strips, whereafter the side of the strip to be fastened is brought against the different tapes. In the latter case, the strips are attached to the flexible carrier by means of different pieces of double-sided tape.

Alternative to the flexible support is the use of an aluminum or polymeric film, for example in aluminum film.

An alternative cross-section of the strips is shown in Figure 4. Each strip has a section according to a symmetrical trapezium with the truncated corners between the sloping sides and the longest side. The angle between the sloping side and the long side is approximately 45 °

The flexible and thermal insulating sheath 1 can be wrapped around a cylindrical object 100, for example, a conveying medium for conveying a heated fluid, as shown in Figure 5. The sides of the sheath are bent around an axis 101 sheath, which axis which is parallel to the longitudinal direction of the fires. By allowing this axis to coincide with the axis of the cylindrical object 100 to be coated or encased, the sheath 1 can curve around the outer wall of this object. The flexible carrier 1000 is located on the outside of the jacket in this case, and the strips 1010 contact the object 100 to be coated, for example a tube. The flexible carrier 1000 has a rectangular circumference, and the strips 1010 cover substantially the entire surface of the flexible carrier 1000.

Alternative embodiments of jackets (1001,1002,1003,1004, 1005, 1006, 1007,1008) are shown in Figures 6a to 6g and 7a and b. The flexible carriers have different shapes, for example trapezoidal (1100), one

BE2017 / 5903

2017/5903 shape with one or two partially curved sides (1200, 1600, 1700,1800), a whimsical shape (1300), or the shape (1400) of, for example, a rectangle with an incision. The strips, which can have the same or different shapes, lengths and / or widths (1110, 1210, 1211, 1310, 1410, 1610, 1710, 1810) cover a large part of the flexible carriers (1120, 1220, 1320, 1420 , 1520, 1620, 1720, 1820). This choice of forms of flexible carriers and directions and forms of strips ensure that different forms of curved objects can be covered.

The embodiment of Figure 6b can be used, for example, for coating the outside of a dome-shaped surface 1250, as shown according to section BB ". The piece with strips 1210, where the strips are narrower than the strips 1211, is used to coat the more cylindrical part of the surface 1250. The piece with strips 1211 is then used to cover the dome of the dome.

A plurality of groups of strips can also be provided on one and the same flexible carrier 1520 with a sheath 1005, as shown in Figure 6h.

The casing 1006 according to the embodiment of Figure 6d can be used, for example, for covering a bend segment of a casing for covering a tube, an additional pipe possibly having to be included in the bend. An opening 1630 may be provided to allow that conduit to pass through the jacket. The bend segment can be a part of a segmented, for example, welded pipe, or a support point, or can be a part of a drawn pipe. Figure 6e shows an alternative to a casing 1007 for covering a bend segment, which can interact with a casing 1008 as shown in Figure 6f. Again, an opening 1730 can be provided for accommodating an additional conduit which connects to the bend to be covered. The maximum width B2 of the jackets 1006 and 1007 corresponds to the length of the pipe to be coated in the axis direction at the

BE2017 / 5903

2017/5903 outside of the curve of the bend segment. The minimum width B1 of the jackets 1006 and 1007 corresponds to the length of the pipe to be coated in the axial direction on the inside of the bend segment curvature.

The sheath 1008 as shown in Figure 6f is used to turn the bends of the tube. The maximum height C2 is typically only half the maximum height B2 of the other jackets 1006 or 1007, often in case a flange is provided immediately after the bend in the tube to connect the bend to a straight piece of tube. The minimum width C1 corresponds to the length of the pipe to be coated in the axis direction on the inside of the curvature of the first or last bend segment. But, for example in the case of a welded or pulled pipe, the length C1 can be made longer to insulate part of the remaining pipe work.

The use of the jackets 1007 and 1008 is shown in Figure 6g. Two jackets 1008 are used to coat the onset of the bend of a tube 3000 adjacent to the respective flanges 3010. The bend itself is subdivided into segments, each of which is covered with a sheath 1007. It goes without saying that only the segment where an additional pipe is to be accommodated is provided with a suitable opening 1730.

As shown in Figs. 7a and 7b, the inside of a combustion device 2000 (only partially shown for the sake of clarity of the figure), which combustion device is provided with a fire glass 2001, is covered with a jacket 1004. The strips 1410 have a longitudinal direction in the axis direction of the cylindrical combustion device 2000. The flexible carrier 1420 is placed against the inside of the combustion device wall while the strips 1410 are pushed laterally against each other. At the level of the fire glass 2001, the notch 1430 is positioned so that it remains protected in the combustion device.

BE2017 / 5903

2017/5903

It is understood that although the embodiments and / or materials for providing embodiments of the present invention have been discussed, various changes or changes may be made without departing from the scope and / or spirit of this invention.

Claims (26)

1 A flexible and thermal insulating sheath suitable for covering the inner and / or outer surface of a curved object, said sheath comprising a flexible support to which a plurality of thermally insulating strips are adhered, each of the strips, each strip comprising a mixture comprising thermally insulating particles, has • two main surfaces that are rectangular, triangle or trapezoidal, • two end surfaces and • two side surfaces, the cross-section of each of the strips along a plane perpendicular to their main surfaces and perpendicular to the longitudinal direction is selected from the group of rectangles, trapeziums and trapeziums with the truncated angles between the oblique sides and the longest side, the adjacent side of each two adjacent strips being substantially parallel and at the level of the attachment to the flexible carrier are separated from each other, and wherein the thermally insulating parti airgel particles, pyrogenic metal oxide particles or a combination of both. A flexible and thermal insulating sheath according to claim 1, wherein the cross-section of each of the strips is a geometric shape selected from the group of rectangles, symmetrical trapezoidal and symmetrical trapezoidal, perpendicular to their main planes and perpendicular to the longitudinal direction. the truncated angles between the oblique sides and the longest side, which shape is symmetrical with respect to a longitudinal direction. 2017/5903 BE2017 / 5903 A flexible and thermal insulating sheath according to claim 1 or 2, wherein the side-by-side side of each two side-by-side strips are separated at a height of at least 0.5 mm from each other at the level of the adhesion to the flexible support. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the strips have substantially identical shapes. A flexible and thermal insulating sheath according to any one of the preceding claims, wherein the maximum thickness of the adjacent sides of two adjacent strips is M, the distance between adjacent sides of two adjacent strips is between 1 mm and M + 20 mm. A flexible and thermal insulating sheath according to any one of the preceding claims, wherein the strips have an average thickness of 1 mm to 80 mm. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the strips have a substantially uniform thickness. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the strips have a spring in the longitudinal direction of 20 mm to 1500 mm. A flexible and thermal insulating sheath according to any one of the preceding claims, wherein the strips transverse to the 2017/5903 longitudinal direction and parallel with the main surfaces have a length of 10 mm to 1500 mm. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the flexible carrier is a textile fabric or foil. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the strips are bonded to the flexible support by means of adhesive and / or double-sided tape. A flexible and thermal insulating jacket according to any of the preceding claims, wherein the shape of each of the strips is provided by a mold-pressed mixture comprising thermally insulating particles. A flexible and thermal insulating jacket according to claim 12, wherein the mold-pressed mixture comprising thermally insulating particles is encased in a textile cloth. A flexible and thermal insulating sheath according to any of the preceding claims, wherein the geometric shape of the cross-section has rounded corners. A flexible and thermal insulating sheath according to any one of the preceding claims, wherein the geometric shape of the cross-section is a symmetrical trapezium, the angle between each of the oblique sides and the large side being between 30 ° and 90 °. BE2017 / 5903 2017/5903 BE2017 / 5903 A flexible and thermal insulating jacket according to claim 15, wherein the strips are adhered to the flexible support along the long side of their symmetrical trapezoidal section. A flexible and thermal insulating sheath according to any of the preceding claims, wherein the thermally insulating particles form part of a thermally insulating mixture comprising 30 to 90% w thermally insulating particles; • 1 to 50% w infrared opacifier or adsorbent; • 0 to 30% w staple fibers; • 0 to 30% w endothermal material; • 0 to 20% w microsilica. A flexible and thermal insulating sheath according to any of the preceding claims, wherein the thermally insulating particles comprise pyrogenic silica particles. A flexible and thermal insulating sheath according to any of the preceding claims, wherein the thermally insulating particles comprise silicon oxide (silica) airgel particles. A flexible and thermal insulating jacket according to any one of the preceding claims, wherein the mixture in the strips has a density of between 50 and 500 kg / m ³ . A flexible and thermal insulating sheath according to any of the preceding claims, wherein the corners of the geometric shape are rounded. 2017/5903 BE2017 / 5903 A flexible and thermal insulating sheath according to claim 21, wherein the radius of the rounding varies between 0 and half the average thickness of the strip. A flexible and thermal insulating sheath according to claim 21 or 22, wherein the sector of the rounding varies between 0 and 90 °. The use of a flexible and thermal insulating sheath according to any one of the preceding claims, for thermally insulating the inner and / or outer surface of a curved object. The use of a flexible and thermal insulating jacket according to claim 24, wherein the article is selected from the group consisting of tubes, cone, bends, domes and / or ovens. 26. - The use of a flexible and thermal insulating sheath according to claim 24 or 25, wherein the flexible and thermal insulating sheath is used to coat a portion of the inner surface of an oven wall.