DE8717044U1 - Cross-sectionally stable, sewn fabric hose for guiding gaseous media - Google Patents

Description

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Applicant: Eckhard Fähnrich

Bäderstrasse 47 a, 2401 Ratekau

Cross-sectionally stable, sewn fabric hose
for guiding gaseous media

The innovation relates to a cross-section-stable fabric hose for guiding gaseous media, consisting of at least one cylindrical hose layer and wire support means that keep the hose layer stable in cross-section, wherein the
Tubular layer - made from a fabric strip of desired length, which is formed into a tubular body and sewn along its longitudinal edges.

In a known hose of the aforementioned type, the hose body consisting of one or more silicate fabric layers is manufactured in such a way that first a fabric strip
or a fabric strip of the desired length is cut, which is then formed into a cylindrical tube body by spiral shaping of the strip or the strip and is sewn at the longitudinal edges that meet in this way/ so that a spirally sewn tube inner layer is created. «Along the spiral-shaped inner seam, due to the

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Spiraling of the silicate fabric strip creates a spiral seam along the entire length of the inside of the hose, which is often folded over to improve the mechanical strength of the inner layer of the hose. Due to the relative stiffness of the silicate fabric, the inevitably spiral seam is relatively wide and protrudes relatively far into the inside of the hose, so that there is considerable flow resistance for hot gases flowing through the hose if the entire hose is assembled in the wrong direction. In addition, it has been found in practical use that the mechanical tear resistance of the hose is not sufficient when sewn in a spiral shape, especially when there are few fabric layers, due to the weave of the silicate material, if such a hose is flowed through by gases at high flow rates.

The innovation consists in the improvement of a sewn fabric/-&ggr;! hose of the type mentioned in the introduction, in which the flow losses on the inside of the hose are considerably reduced and which has an improved mechanical tear resistance at high flow velocities. ^; "

The solution to the problem is based on the fabric tube mentioned at the beginning and is characterized in that the fabric strip is formed into a cylindrical tube body perpendicular to its longitudinal extension and that the two longitudinal edges of the strip thus formed are connected to one another by means of an axially parallel stitching.

This solution eliminates the need for a spiral seam on the inside of the hose, so that when it is attached

It is no longer necessary to pay attention to the direction of flow of the gases flowing through the hose, as there is no longer a spiral or quasi-ring-shaped overlap area which creates a flow resistance. Instead, there is only a longitudinal seam on the inside of the hose which is parallel to the longitudinal axis of the hose and which, understandably, cannot create a flow resistance. As the inner fabric layer is sewn lengthwise, this fabric layer can be regarded as axially one-piece in the longitudinal direction, i.e. in the direction of extension of the hose, and therefore has no areas weakened by sewing in the direction of load, so that the full load-bearing capacity of the fabric material in the longitudinal direction of the hose is fully available and _can be used accordingly. There is therefore no longer any risk of the hose being torn apart at the seam by the flow load of fast-flowing gases and/or by mechanical tensile load.

The innovation is explained below using an exemplary embodiment shown in the attached drawing, whereby the drawing shows the exemplary embodiment in a longitudinal section that is only partially shown.

The example shown consists of at least one inner tube layer 1 made of silicate fabric material, a wire coil 2 surrounding the tube layer on the outside to support the tube layer, a spiral-shaped, heat-resistant material strip 3 for securing the wire coil, the strip being connected to the tube layer 1 by the spiral seams 4 and 5.

■n is sewn together, and of at least one outer hose layer 6 made of heat-resistant material which coaxially surrounds the aforementioned parts. The hose layers 1 and 6 are connected to one another at the two hose ends by seams 7 and 8.

In the simplest embodiment, the hose, generally designated 9, can consist of parts 1 to 5, which means that the thinner layer 6 can be omitted. It is also possible, however, to have several inner layers made of silicate fabric material and several outer hose layers made of more or less heat-resistant material, whereby gas-tight inserts (not shown) can also be inserted. Such a hose is resistant to high temperatures and is used primarily with the hottest gases.

Alternatively, the outer hose layer 6 or the outer hose layers can be made in any shape and manner and from the desired fabric material. The or each innermost hose layer 1 can also consist of a fabric web or strip other than silicate fabric, which is formed perpendicular to its longitudinal extension into a cylindrical hose body, i.e. is not coiled, so that the two longitudinal rail areas 10 and 11 overlap to form a longitudinal space 13 that is axially parallel to the longitudinal axis 12 of the hose 9 and are connected to one another with an axially parallel seam made of, for example, two straight longitudinal seams 14 and 15. Such a hose is used primarily for low-temperature gases.

Silicate fabric is a known fabric whose fibers generally consist of at least about 90% SiO ₂ . Such a fabric must be used for the inner hose if it is directly exposed to the high temperatures of hot exhaust gases or the like. A mixed fabric can then be used for the following hoses, which, in addition to silicate fibers, also contains other high-melting fibers with low thermal conductivity, which consist of glass fibers, for example, and can be used for the fabric of the outer hose layer, for example.

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The diameter and length of the hose can be arbitrary and depend on the intended use of the hose.

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Claims (2)

HatantenwSlte " &Idigr;&Igr;&iacgr; '". * *; \!**"· Dr. Hugo Wilcken ,;!, \\\ ' .·,,;*.* i'l l' 28.12.1987 DfpNng, Thomas Wilcken " " Musterbehn 1 · 2400 Lübeck 1 Applicant: Eckhard Fähnrich Bäderstraße 47 a, 2401 Ratekau Protection claims 1. Cross-sectionally stable, sewn fabric hose for guiding gaseous media, consisting of at least one cylindrical hose system and wire support means that keep the hose system stable in cross-section, the hose layer being made from a fabric strip of the desired length that is formed into a hose body and sewn at its longitudinal edges, characterized in that the fabric strip is formed perpendicular to its longitudinal extension into a cylindrical hose body (1) and that the two longitudinal edges (10, 11) of the strip formed in this way are connected to one another by means of an axially parallel stitching (14, 15). 2. Hose according to claim 1, characterized in that the fabric strip (1) consists of a silicate fabric. &bull;# iiii tt i ti 1 i t i f I * I t