DE2044695A1 - Protective device - Google Patents

Description

Dr. F. Zumetaln Sr. - Dr. E. Asemann Dr. R. KoenlgeberQer. DlpL-Phys. R. Holzbauer Dr. F. Zumsteln Jun.

PATENT LAWYERS TELEPHONE: COLLECTIVE-Mt. 339341 TELEGRAMS: ZUMPAT PUSTSCHECK ACCOUNT: MÖNCHEN Ml 3 »

BANK ACCOUNT: BANK H. AUFHAUSER

8 MONKS a,

Case RC 4696

THE DUNLOP COMPANY LTD., LONDON / Great Britain, Protective device

The invention relates to guards and, more particularly, to doors and partitions for use in pits.

For safety reasons, it is necessary in pits to provide doors or partition walls that prevent the spread of fire and also have an absorbing effect on pressure waves. These doors or partitions are placed at strategic points within the underground system in an effort to reduce the impact to keep an explosion as low as possible. The doors and partitions previously used in pits are simple gas chippings and are relatively ineffective, which prevents the absorption of Blast waves and stopping fire. They have

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also the disadvantage that they tend to interfere with the ventilation of the pit.

According to the invention a door or partition for use in pits comprises at least a part, and preferably at least in a larger part a porous refractory material, which has the shape of a three-dimensional network frame with has many cellular cavities that communicate with each other stand. The refractory material can be metal, ceramic, or ceramic-coated metal. The porous metal structure can be made, for example, by coating a porous substrate with a metal, for example by electroplating a conductive porous substrate. The porous ceramic structure can be formed by depositing the ceramic Material can be made from a slurry onto a porous substrate.

The conductive porous substrate can be a porous plastic material which is made conductive by itself or which is made conductive by a surface treatment. Is beneficial a reticulated polyurethane foam as a porous plastic material.

The porous substrate may or may not be in the form of an agglomerate of fibers, such as a matted material a sponge-like or foam material such as a natural sponge or a synthetic resin foam. In general, polyurethane foams are used preferred. The porous material can be removed, for example by heating, to the material melt or "wash out".

Where a high degree of porosity is required, the Foam can be a reticulated foam, i.e. a foam in which the organic fiber forms a three-dimensional network without strong wall parts delimiting the cells. Such reticulated

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Foams can be made by removing the relatively thin cell walls from a foam, for example with chemical Agents such as aqueous sodium hydroxide in the case of polyurethane foams.

If the metal is electrodeposited it is of course necessary to use either a porous material that is electrically conductive, or conduct the material with the help of a » to make the surface layer conductive. Non-conductive materials can be made with the help of additives such as graphite or metal powder be made self-guiding. A conductive surface layer can be attached by coating the material with a curable resin material that has a conductive additive contains, or by chemical deposition of a metal, for example by reducing ammoniacal silver nitrate in situ. If chemical deposition is used, generally the surface should be coated with one or more sensitizing agents Agents are treated, such as tin chloride and then palladium chloride for silver.

Alloy structures of the first metal can be used in some cases by direct plating, in other cases two or more metals can be deposited in sequence and the alloy is formed by heating the resulting structure. Steel foams can be made by storing the required Amount of carbon and / or nitrogen can be generated. The carbon can come from an organic material, which forms the basic foam, originate from or can be added to an electroplating bath.

In general, pore sizes can range from 4 pores per cm to;

40 pores per cm can be used, whereby it should be noted that the coarser pore sizes have a greater resistance against damage from heat. Therefore, a composite structure with a coarse pore is often desirable

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Foam closer to the assumed heat or fire source and a fine porous foam on the other side.

To make the door or partition more resistant to heat or corrosion. she can make an alloy such as contain a nickel-chromium alloy. Methods for making such porous alloy structures are disclosed in US Pat related German patent application P 19 41 494 and P 20 30 115 described.

In one embodiment of the invention, the doors or * Partitions, frameworks into which fillings of the porous refractory material are fitted.

The frameworks are usually made of wood, but they can also be made of other materials such as metal, in particular aluminum or a light metal alloy.

Ε1η · _; ΐ Ausfübruncrifarm the invention is as an example based on the. o · ... he judges ·. Drawing explained. The only figure shows a "■ 'rrr_;: · - · :; HIr * ri t: h ^ lz frame with z-vjei different construction ™

rur ^ sf orr. < α-Γ Srtification Un; -

^ hriier. 1 to the left: ijölzerne .: C ...: erstück ^ ri 2. In the yard

■, · -: ■: i: ^ r ScnauuiieL "? ^; 1." :. ? f.:i;'.ce,; puking, The doors are

ώ,. ::;: · .ηΛ \:.;, ί; ^ ς! ^: Γί: α / :. ώη Taren uiid Trenn-Wand'- r, aiten v; i.rkungsvoll?; ü: .. · R. ^f / ^: v ^ t -;: \ on and limit an explosion <'i.'': ■. ■ -.- r ■': ■. ■■ -: r:;. ü ;;;; -; ; e Zone ii: the pit »Also possible. they (X ¹ .: .''-.! ";L; r. tv of gases, so that they disturb the mine ventilation l: ir d;: -.-. r: .- c-.l to the same extent as the conventional massive r: ¹ JTi ¹ JT :; f ^j .. ';r; walls »

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Claims (14)

Claims 1. Door or partition for use in pits, thereby
characterized in that at least part of a porous
refractory material is there; s the shape of a three- ... .. ^ dimensional network framework with many cell-shaped
Has cavities that are in communication with each other. 2. Door or partition according to claim 1, characterized in that that at least a larger part consists of a porous refractory material 3. door or partition according to claim 1, characterized in that the refractory material is a metal and / or a ceramic Fabric is. 4. door or partition according to claim 3, characterized in that the porous refractory material is a ceramic coated Metal is. 5. door or partition according to any one of the preceding claims, characterized in that fillings of porous refractory Material are held in a framework. 6. door or partition according to claim 5, characterized in that the frame structure consists of wood. 7. door or partition according to claim 5, characterized in that the frame structure consists of metal. 8. door or partition according to claim 7, characterized in that the frame structure consists of aluminum. 109817/1224 9. door or partition according to claim 7, characterized in that that the framework consists of a light metal alloy. 10. Door or partition according to one of the preceding claims, characterized in that the porous refractory material is made by depositing metal or ceramic material on a porous substrate. 11. door or partition according to claim 10, characterized in that the metal is deposited electrolytically. 12. door or partition according to claim 10, characterized in that the porous substrate is a reticulated foam. 13. Door or partition according to claim 12, characterized in that that the porous substrate is a reticulated polyurethane foam, 14. Door or partition according to one of the preceding claims, characterized in that the porous refractory material has between 4 and 40 pores per cm. 109817/1224