DE2530667C3 - Heat-resistant laminate - Google Patents

Description

The invention relates to a heat-resistant laminate made from a web of fabric woven into it Metal threads and metal foil connected on one side to the fabric web.

In a known laminate of this type (DE-PS 5 39826), a part of the warp u- \ d weft threads of the fabric web of metal fibers, in particular aluminum threads, in the form of metal foil strips or to cord-like structures twisted metal foil strips or threads having a core of cotton "Silk," full or the like. The other warp and weft threads are textile threads. The metal foil, in particular aluminum foil, is sewn to the fabric web. However, by sewing the fabric sheet and the flat metal foil, the gas and liquid tightness of the laminate, which is indispensable for many applications, is lost. The seams can easily break under high loads; there is a risk of the metal foil becoming detached from the fabric layer.

It is also known (DE-PS 8 08 342), non-combustible fabric on the flame or heat to provide the facing side with a thin, laminated metal foil, in particular aluminum foil. To connect the film and fabric layer, a flame-retardant adhesive, varnish or the like can be used. Because the adhesive bond is on the heat-exposed side of the laminate is located and the metal foil has a high thermal conductivity, the temperature resistance of the Laminate largely due to the comparatively low thermal resistance of the adhesive bond certainly.

There are also known asbestos fabrics made of yarn (DE-PS 19 406), in which a metal insert in the form an iron, steel, copper, brass, platinum or zinc wire is so spun with asbestos fibers that the insert is evenly enclosed on all sides. Such an asbestos fabric can also be used Production of pipeline connections find use. The disadvantage of this asbestos fabric is that it is gas and liquid permeable.

The invention is based on the object of providing a corrosion-resistant and heat-resistant laminate of high To create flexibility in which there is a - and Liquid impermeable wedge can guarantee up to extremely high temperatures,

This object is achieved according to the invention in that the metal threads and the metal foil are made of stainless steel and that the metal foil is connected to the fabric web by spot welding.
The fabric sheet with woven-in stainless steel threads is characterized by particularly high heat resistance and corrosion resistance as well as high tear values. The stainless steel foil causes a further improvement of the chemical, thermal and unc * Or

ίο mechanical strength of the laminate. Through the The spot welded connection becomes a particularly reliable one without any significant impairment of flexibility Cohesion of fabric sheet and metal foil achieved. Such a weld acts as a fusion of the S-liner with lying on the fabric surface Rod wires in the area of the respective contact points. There is a detachment of the film from the fabric web excluded even at the highest temperature loads. The gas and liquid tightness remains obtain.

In a further embodiment of the invention, the fabric web can each have a metal foil on both sides be connected. Such a laminate has high abrasion resistance on both sides. The fabric panel is protected on all sides against mechanical and chemical stress. Also against heat radiation The metal foils offer protection on both sides.

The heat-resistant laminate designed according to the invention is particularly suitable for producing elastic connections (expansion joints) of pipelines or the like. The steel wire reinforcement and the steel foil punctured onto the fabric web the compensator a compared to known tissue compensators, z. B. Compensators made of As-

jc best fabric, significantly increased mechanical strength. The heat and acid resistance are also decisively / improved. The laminate can be z. B. use as a protective layer on the outside and inside walls. Pickled in as the outer layer, a soft

• 40 fabric compensator with a flexible, acid-proof outer wall that is safe against heat radiation from the outside. As an inner layer, the laminate offers reliable protection against the dreaded condensates and against abrasion. The properties and operating data of a fabric expansion joint are significantly improved in this way. Additional areas of application are opened up for the fabric compensator. He can first apply undiminished flexible characteristics while maintaining its Abdichtnngsfunktion and all sides are loaded with more than 300 ^0C. In view of the high flexibility, the expansion joint can be given a profile shape that is adapted to any application.

The subject matter of claims 2 and 3 can only be enjoyed in conjunction with the subject matter of claim 1 Protection.

The invention is explained in more detail below on the basis of preferred exemplary embodiments. In shows the drawings

M) Fig. 1 is a schematic cross section through a Laminate according to the invention with metal foil applied to one side of the fabric layer and

F ί g. 2 shows a partial cross section of a built up using the laminate according to the invention

h5 fabric expansion joint,

1 schematically illustrates a fabric 25 made of heat-resistant yarn, for example made of asbestos fibers or acid-proof, high-strength, synthetic

Mineral fibers spun with stainless steel wires. The weft and warp threads of the fabric 25 are denoted by 26 and 27, respectively. In the weft threads shown in cross section are the stainless steel wires indicated at 28. A foil 29 made of stainless steel is pressed onto one side of the fabric 25. For one Connection between the fabric 25 and the foil 29 is ensured by the fact that the steel wires are attached to the foil 29 facing surface of the fabric 25 is spot-welded to the steel foil at the respective contact points are. The steel foil 29 preferably has such a high inherent flexibility that it has the flexibility of the Tissue is not noticeably impaired. If necessary, a second steel foil can be attached to the underside of the Fabric 25 are provided. It can also be useful for certain applications, several to combine alternating fabric and film layers into a bonded laminate.

An elastic connection (compensator) according to FIG. 2 is used to connect two pipes, whose ends facing one another are denoted by 1 and 2. The direction of flow in channel & l is with indicated by arrow 3. A fastening flange 4 and 5 is welded to each of the two pipelines. The pipe end located upstream in the direction of flow also carries on its inside a deflector ring 6.

The inner layer of the crease-free compensator, designated as a whole by 10, consists of a garland wire mesh 11, which has a filling made of a highly heat-resistant felt layer 12 and a mineral wool layer 13 encloses. The layer 13 closes

to the outside a sequence 14 of layers, at least one of which is a laminate according to the invention, whose steel foil forms the sealing element of the compensator or the sealing effect of a separate one sealing element, for example in the form of a polytetrafluoroethylene film, can support.

The in Fig. The upper end of the compensator is fixed to the flange 4 by means of a clamp 15 which is pulled together by a screw 16. A modified type of fastening is illustrated for the lower end of the compensator 10, in which the screws 18 penetrate bores in the flange 5 and in the protruding edge of the compensator. The screws 18 also extend through a clamping reinforcement 19 and a flat iron 20. By tightening the nuts 21 sitting on the screws 18, the compensator is clamped between the fastening flange 5 and the flat iron 20.

According to a modified embodiment, the inner layer of the compensator can also be advantageous consist of a laminate of the type shown in FIG.

The stainless steel foil spot-welded to the fabric layer preferably has a thickness of bii. to 0.075 mm. Foil thicknesses of approximately 0.05 mm have proven to be particularly suitable. Such foils are not self-supporting. In terms of inherent flexibility, they are rather comparable to cigarette paper. The flexibility of the fabric sheet therefore also remains for the one made up of fabric sheet and steel foil Laminate is practically fully preserved.

For this 1 sheet of drawing cords

Claims (3)

Patent claims: 1. Heat-resistant laminate made of a fabric web with woven metal threads and Metal foil connected on one side to the fabric web, characterized in that the Metal threads and the metal foil consist of stainless steel and that the metal foil with the fabric web connected by spot welding. 2. Heat-resistant laminate according to claim 1, characterized in that the fabric web is connected on both sides with a metal foil 3. Use of the heat-resistant laminate according to one of the preceding claims for Production of elastic connections of pipes or the like.