DE2405129A1 - PROCESS FOR COVERING PIPES - Google Patents

Description

PATENT Attorney DiL HANS-GÜNTHER EGGERT ₁ DIPLOMA CHEMIST

5 COLOGNE 51, OBERLÄNDER UFER aO 2405129

Cologne, February 1st, 1974

Eg / Ix

FOSECO International Limited

Long Acre, Nechells, Birmingham, B7 5JR / England

Process for sheathing pipes

There are numerous cases in industrial plants where piping Have to deal with a jacket “The jacketing of pipelines in ovens, in which the pipelines are quickly damaged.

A "special problem exists in the case of slab pre- heating furnace through which the metal slabs after storage be guided in the storage area and before rolling so that they can be heated from above and below. to for this purpose two rails are provided and the slabs to be preheated are pushed along the rails.

These rails are made of steel and are driven by water, which is circulated through the rails and their supports, cooled to prevent them from becoming too hot and damaged will. It is common practice to cut the piping and the lower parts of the rails, i. E. which are not in with the slabs Insulate the file that comes into contact with it to reduce the amount of heat lost from the oven as a result of cooling and also to protect the pipelines *

Numerous methods have already been used for sighting and Suggested insulation of the pipes. This includes the lining and putting on of semi-cylindrical shells refractory material. Many of these methods are time consuming and cumbersome to carry out and in general practice

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unsatisfactory. For example, "in many methods Metal clamps, brackets or straps are used, which themselves erode during the operation of the furnace, so that the insulation subsequently falls apart. It should be emphasized that on the conditions during the operation of the furnace a very considerable attack by the heat and by slag, exposure to flames and very considerable vibrations born

Some success has already been achieved by using 1Q half-shells that are placed around the pipeline, and a refractory layer is then sprayed onto the outside of these.

The invention relates to a method for sheathing pipes, which is characterized in that part of the pipe is surrounded by a channel-shaped component of generally U-shaped cross-section, and the remainder is surrounded by a closure plate which bridges ^{the open end of the B U tt} and is arranged so that it cannot be removed radially from the pipe without breaking the plate or the trough-shaped member, and fills the space between the pipe and the member and the plate with heat-insulating refractory material.

In one embodiment of the invention, you insert D-shaped profile and a locking slat, both made of fire-proof thermal insulation material, to surround the pipe, holds them in place, bonds them with a hardenable refractory cement and lets the cement harden Parts of the U-profile and the closure plate are shaped so that the hardened cement has the shape of a Adopts locking or locking part »

Under the expression "locking or locking part * it is to be understood that the U-profile and the closure plate must have such a shape that the cement after for example, forms a row or bar after hardening,

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which does not allow the plate to be removed from the pipe in the radial direction without breaking the plate or the U-profile will. In this aspect of the invention, the set cement provides as opposed to "prior art methods." those of the refractory cement only as a jointing and connecting material. is used where the strength of the two interconnected parts depends on the adhesive strength of the cement, constitutes a connecting piece, which is mechanically wedged in its position so that the dismantling of the plate and U-profile is prevented.

In one embodiment of the U-profile and the closure plate the latter consists of an elongated flat brick · The insides of the upper ends of the U-profile approach each other conically, and the long edges of the brick are grooved, so that the hardened cement after assembling these two parts with a refractory cement forms a shaped body which mechanically wedges the two pieces together.

In another embodiment of the invention, the pipe is encased by a U-profile and a closure plate Made of fire-resistant thermal insulation material around the pipe, forming a jacket that completely covers the pipe surrounds, laid, the pieces are bonded together with a hardenable refractory cement and grouted and the Cement hardens or is left to harden, the nested parts of the U-profile and the closure plate are shaped to interlock so that the parts are held together during the Cement sets and hardens.

The expression "interlocking form" means that the two parts must be shaped so that, after the cement has hardened, a shaped body, e.g. Wedge is formed which prevents the pieces from being removed radially from the pipe without either of the pieces or

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both break. The preferred formations for this purpose are interlocking, complementary, conical Surfaces.

'. In this embodiment, the hardened cement sets * Is a connecting piece, the adhesion of which is added to the mechanical wedging or interlocking of the pieces and prevents the two parts from falling apart. The mechanical Toothing and wedging is preferably made so that the insides of the upper ends of the U-shaped component are provided with a conicity that the conicity of the interacting sides a brick engaging therein and forming the closure plate.

In certain cases, the U-shaped member and the closure plate are not grouted with cement so that they can move relative to each other and thereby avoid deformations and tensions when the Tube is heated or cooled. In such a pail, the parts must be shaped accordingly by, for example the U-shaped part is provided with two inwardly projecting paddles on which the closure plate rests.

The between the pipe and the U-shaped component and the Closing plate provided layer of refractory material is preferably deformable in order to be adaptable to lend to the pipeline and fittings. As materials are suitable for this purpose Mushroom materials or woven blankets that are wholly or predominantly consist of inorganic fibers, e.g. glass fibers, rock wool, mineral wool and ceramic fibers For example, aluminosilicate fibers are particularly advantageous.

The components that together form the jacket around the pipe »can be made from a wide variety of refractory heat- treat- 409832/0871

materials are made. Molten cement is preferred, but other materials, e.g. Cement-set fine-particle refractory materials, refractory fibrous materials set with colloidal hydroaol and refractory concrete are used, these Materials can optionally be reinforced with short metal wires or ceramic fibers.

The processes for producing the shaped bodies from refractory materials of this type are generally known and do not require any further description here.

The method described for sheathing of pipelines can of course also be applied to two or more pipes running next to each other, e.g. two pipes with practically the same diameter and in wetntal parallel axes, to sheath.

The invention is explained below in connection with the figures.

1 shows a section through a sheathed single sliding tube.

Fig. 2 is a section through a double tube encased according to the invention

Figure 3 is a cross-section similar to Figure 1, but one alternative embodiment.

Fig.4- is a similar cross-section through another Embodiment.

In the designs shown in FIGS. 1 and 2, the tube b «w are. the pipes 1 from a casing ' UBieben, which consists of two refractory parts 2 and 3. The pieces 2 and 3 are held together with a hardened refractory high temperature cement 4. The space between the pipe and the casing formed from the pieces 2 and 3 is with a zueanmendrückbaren

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elastic refractory fiber matire 5 filled.

The casings are assembled over the pipes as follows: The edge of the upper U-shaped part 2 is provided with several holes into which short rods are inserted will. These rods protrude through the holes in grooves 6 on each side of the plates 3. The refractory Cement is then pressed into the interstices, or it can be used prior to the assembly of part 3 and part 2 be applied. In both cases the rods 7 hold the two parts together until the refractory cement has set Has. The rods can be made of any suitable material such as metal, ceramic, plastics, wood, cardboard etc. exist. Suitable metals are, for example, aluminum, iron, steel, zinc and their alloys Metals. Aluminum and zinc melt and leave little residue. It is also possible to make the rods out of rigid Manufacture plastic, wood or stiffened cardboard. All of these materials burn out and leave behind practically little or no residue. In cases where permanent bars are considered appropriate, Rods made of ceramic material can advantageously be used, as the ceramic material · during the entire Lifespan of the cladding material remains firm and coherent. Due to the groove 6 and the conicity of the inner surfaces 8 of the U-shaped component 2, the set and hardened cement forms a firmly interlocked one Component that holds the casing together around the pipe.

3 shows a pipe 10 which is surrounded by a casing which consists of two refractory parts 11 and 12.

The component 11 is generally U-shaped.The mutually facing inner surfaces 13 de U approach each other conically, so that the transverse distance between the surfaces 13 in the direction to the free ends of the U garinger. The component 12 has the cross section of a Trapezee, its outer sides 14 eich extend along the pipe and a Konisltät

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have that supplemented that of the surfaces 13

In this way the surfaces 13 and 14 can be wedge-shaped interlocking «. In addition, the parts 11 and 12 are replaced by two at the corners between the parts 11 and 12 arranged webs 15 held together from refractory cement. Most of the space between the Tube 10 and the casing formed from parts 11 and 12 is provided with a compressible, elastic, Refractory fiber mat 16 filled, with an air gap 17 remains between the mat 16 and the cladding. The air gap 17, however, can optionally be eliminated by covering the entire tree with refractory fibers is filled in *

In practice, the casing around the pipe 10 is assembled as follows: The mat 16 is first around the Pipe laid or stuffed in the space between the casing and the pipe. When the tapered faces 13 and 14 have been brought into the desired wedge-shaped engagement achieved by the plate 12 is pushed into the component 11 in the longitudinal direction, the cement joints 15 are made in the required position. Clamping parts 11 and 12 are held together while the cement in the joints sets and hardened.

The embodiment shown in Figure 4 is advantageous under conditions under which the U-profile and the Plates tend to expand or contract unevenly. This can lead to breakage of one or more other component or, in severe cases, cause the plate to fall out.

In this embodiment let one pipe 20 of one Envelope «21 surrounded by fiber material« About the pipe is «in Channel-shaped component 22 in the form of an * inverted U

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put inside. This component is held on the tube by a plate 23, which during assembly in the longitudinal direction is inserted and rests on two paddles 24 of the component 22. The plate 23 is dimensioned so that on a gap 25 remains free on each side. These columns take a different movement of the U-shaped Component and the plate when they are heated or cooled.

Of course, there are numerous variations of those described above simple systems both in relation to the respective iOrm of the parts used and to their Manufacture of the materials used possible. In all cases, the processes according to the invention can be used for Carry out the production of the casing quickly, easily and economically.

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Claims (9)

Claims ίί) Process for sheathing or cladding pipes, wherein one part of the pipe with a channel-shaped component with a generally U-shaped cross-section surrounds, characterized in that one surrounds the rest of the tube with a closure plate, which the open The end of the U-shaped cross-section bridged and turned can not be removed radially from the pipe without breaking the plate or the U-shaped member, and by the space between the tube and the U-shaped Member and the plate with heat insulating fireproof Material fills out. 2) Method according to claim 1, characterized in that the U-shaped component and the plate with a hardenable Refractory cement are connected and grouted, the U-shaped component and the plate being shaped are that the set and hardened cement forms a molded body that interlocks the components. 3) Method according to claim 1 and 2, characterized in that the nested parts of the U-shaped Component and the plate are shaped so that their separation from the pipe is prevented in the radial direction will, 4) Method according to claim 1 to 3, characterized in that the plate has a trapezoidal cross-section and the inner surfaces of the free ends of the U-shaped component have such a conicity and dimension have to fit on the outer surfaces of the plate. 5) Method according to claim 1 to 4, characterized »that the free ends of the U-shaped component with are each provided with an inwardly protruding flange and the width of the plate sizez * is than the inner distance 409832/0871 between the flanges » 6) Method according to claim 1 to 5, characterized in that as a heat-insulating refractory filler material an elastic filling made of refractory fibers is used. 7) Method according to claim 1 to 6, characterized in that glass fibers, rock wool, slag wool or aluminosilicate fibers are used as the refractory fibers will" 8) Method according to claim 1 to 7, characterized in that U-shaped components and plates made of molten cement be used. 9) Method according to claim 1 to 7, characterized in that U-shaped components and plates made of bonded with cement finely divided refractory material, refractory fiber material bound with colloidal hydrosol or refractory concrete can be used. A0 9832/0871 L e r s e i t e