DE2834548A1 - EXPANDABLE RAIL MATERIAL - Google Patents

Description

PATENT LAWYERS

WUESTHOFF - ν. PECHMANN - BEHR ENS - GOETZ

PROFESSIONAL REPRESENTATIVES BErORf ΠΓΕ EUROPEAN PATENT OFFICE MANDATAIRES AGREES PRES l'oFFIC 'r.UROPEEN DES BREVETS

ΓΡ.-ΙΝΊ FRANZ TUESTHOFF

DK. PH.— FREDA WUESTHOFF (1927-1956)

nPL.-fr-G. GERHARD PULS (l ^ jl-l ^ yl) DIPL.-CHEM. DR. E. BARBER OF PECHMANN DR.-ING. DIETER BEHRENS DIPL.-ING .; DIPL.-WIRTSCH.-ING. RUPERT GOETZ

D-8000 MONCH SCHWEIGERSTRASSE

phone: (089) 66 20 ji TELEGRAM: PROTECTPATENT TELEX: J 24 070

1A-51 042 patent notification

Applicant: MINNJiSOTA MINING AND MANUFACTURING COMPANY

3M Center, Saint Paul, Minnesota 55101, US _e A "

Title: Expandable Railway Material

Addition to P 24 41 6 ^ 3.9

909808/088 ^

PATENT AWARDS

WUESTHOFF - ν. PECHMANN - BEKK ENS - GOETZ

PROFESSIONAL REPRESENTATIVE BEFORE HIE KUROPEAN PATENT OFFICE

MANDATAiREs agrees pres l'officf. euuopeen des brevets

'IR-ING FRANZWUESTHOFF

D.;. PKI-. FREDA T7UESTHOFF (1927-1956)

• 1IPL.- ^T NG. GF.RHARD PULS (19J2-I971)

DIPL.-CHEM. DR. E. BARBER OF PECHMANN DR.-ING. DIETER BEHRENS DIPL.-ING .; DIPL.-WIRTSCH.-ING. RUPERT GOETZ

D-8000 MUNICH 90 SCHWEIGERSTRASSE 2

phone: (089) 66 20 51
telegram: protectpatent TELEX: J 24 070

ΙΑ-SI 042

Applicant: Minnesota Mining

B es chr ei bu η g

The main application P 24 41 633 is an expandable Web material, which in addition to 30 to 85 wt .-% expandable or, peelable mica, 0 to 60 wt .-? i! one inorganic fiber material and about 70 to 10% by weight of one contains inorganic binder. The mica is preferably vermiculite, the inorganic binder is hectorite, bentonite, asbestos and / or synthetic fluorine-containing tetrahedral mica. Asbestos is the preferred inorganic fiber material, Soft glass fibers and / or aluminum silicate fibers. The sheet material can optionally be provided with a reinforcing pad such as a Plastic film, kraft paper or a mineral fiber fabric * This sheet material is used in particular for Catalysts in an exhaust gas decontamination system for internal combustion engines ,,

The additional application to the main patent P 25 49 223 now brings a modification of the web material according to the main patent in the direction that 5 to 20% by weight of an organic elastomer are contained as a binder and the web material has a density of at least about 0.5 g / cm in the dry state. According to this, organic binders are particularly suitable Natural rubber, styrene-butadiene rubber, butadiene

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Acrylonitrile rubber and polyacrylate and polymethacrylate polymers or copolymers.

The present application is a further modification of the railway material insofar as it consists of about 40 to Gev, -% unexpanded vermiculite, about 15 to 35% by weight of inorganic fiber material and about 25 to 10% by weight of a combination of an elastomer binder with an inorganic binder in the form of clay in a ratio of about 0.5 to 1.5. An aluminosilicate is preferred as the fiber material and bentonite is preferred as the inorganic binder.

The web materials according to the invention are heat-resistant, compliant after expansion and essentially retain their strength values even after expansion.

It has been found that catalyst systems, such as those used, for example, for the oxidation of carbon monoxide and hydrocarbons and to reduce the nitrogen oxides from the exhaust gases of automobiles, relatively high temperatures at the are exposed to catalytic Frozessen, so that ceramic materials are primarily suitable for this purpose.

Are particularly useful as supports for the catalysts

, - , ^ χ. .. j -, .object

ceramic honeycomb systems, as they are for example / from US-RE 27 747 are.

Ceramic bodies are known to be brittle and fragile and their coefficient of thermal expansion is considerably different from that of the metal containers in which they are housed. The fixation of the ceramic body in the containers must be opposite mechanical effects such as shock and vibration as well as thermal shock from alternating heating and be resistant to cooling. Both stresses, namely the thermal and the mechanical, lead to a double

»Consists of 909808/0889 -3-

1A-51 042

disruption of the ceramic support which - once started - progresses rapidly and eventually that makes the whole catalyst system unusable.

It has now been found that the products after the main application and its additional application in their application lead to some difficulties because the inorganic Binders cause relatively stiff materials that are difficult to roll up on windings with a small diameter.

the
knife or organic binder no longer contribute in any way to the strength after heating.

The material according to the invention can now be rolled up tightly and zvar with a Radtis of 5 cm and below, without cracks occur if it is at least about 2.5 mm thick and furthermore substantially retains its tensile strength after expansion.

The web material according to the invention is in particular in the type of paper production in the desired thickness of about 0.5 to 5 mm.

As the organic binder various dene polymers and elastomers in question, which are used in the form of the latex for the production of the sheet material _P such as natural rubber, styrene-butadiene polymers, butadiene-acrylonitrile polymers or polymers and copolymers of acrylic acid or methacrylic acid.

In particular, the inorganic binder is a clay such as bentonite.

The web material according to the invention is used in catalytic exhaust gas detoxifiers of automobiles or the like by being installed in the exhaust systems and expanded in situ _o

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The expanded sheet material holds the ceramic core or catalyst carrier within the housing or container in place. The heat resistance and compliance of the sheet material after expansion compensates for the differences in the thermal expansion behavior of the metal housing and ceramic insert, cushions the on the brittle Body transmitted vibrations and evens out irregularities

or
on the metallic / ceramic surface.

The material according to the invention can be produced in the manner of paper such as by hand scooping or machine scooping or on paper machines, provided that an even distribution of the components is ensured throughout the material Man-made fiber felt or the like be applied. There are about 40 to 75 Gev.-S-ri unexpanded vermiculite with a grain size of about 0.1 to 6 mm, preferably a maximum of 2 mm in a large volume of water with about 15 to 35 inorganic. Fiber material such as chrysotile or amphibole asbestos, soft glass fibers, ceramic fibers such as ZrOg-SiOp fibers, alumina whiskers or aluminoellicate fibers and about 10 to 25 % binder added, the binder consisting of elastomer and clay in a ratio of 0.5: 1.5. You can also add small amounts of surface-active substances, foaming agents, flocculants or the like to the mass for the production of the railway material «,

The flocculation is generally achieved using electrolytes such as alum, barium salts or nonionic Arylamidpolyelekfcrolyte., Vermiculite, inorganic fibrous material and binder v orden in a large volume of water, for example ₀ in the order of 5 to 100% mixed / and a flocculant was added. A surfactant or foaming agent can also be used to improve the dispersion of the vermiculite

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1Α-51 042

incorporate into the slurry. To see the industrial hygiene Avoiding constraints on the use of asbestos can glass fibers or ceramic can also be used at this point (crystalline or non-crystalline) fiber material or Use whiskers, but asbestos fibers are the cheapest.

As mentioned, the web material can be in the manner of Papermaking such as by hand scooping or on a Fourdrinier machine. The combination of inorganic and organic binder facilitates dewatering of the fiber felt compared to the use of only inorganic binder. The fiber felt obtained is compressed to a dry one

2 density of at least about 500 kg / m and after drying at about 90 ° C is an easily manageable, flexible, resilient, expandable sheet material. A strip of this material with a width of about 2.5 cm and a thickness of 1.5 to 3 mm has a load-bearing capacity of about 0.5 to 2 kg or more and can be bent to a radius of about 4.5 to 6 cm j without tearing. The expansion happens then at temperatures of about 500 to 800 ⁰ C. It is evident that thinner sheet material may bend tighter radii and thicker sheeting to larger radii.

The thickness of the material according to the invention increases as a result of the heating to expand, depending on the concentration of the vermi ^ ulite in the order of about 165 to 300 % . After expansion, the material according to the invention shows good resistance to vibration and mechanical shock, especially when it is very strongly expanded.

When using the material according to the invention with ceramic objects, it is essential (to point out that with an unyielding container during the Ex-

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g 1A-51 042

pansion of the material according to the invention occurring forces can be large enough to destroy the ceramic body. When designing the exhaust systems or the like, the directness and expandability of the material and the distance between the ceramic object and the housing must be taken into account.

The invention is explained further using the following example.

example

About 40% of a rubber latex of 57 parts of butadiene, 10 parts of styrene and 33 parts of acrylonitrile and the corresponding amount of bentonite were added to a large ¥ aring mixer at low speed to 2.5 l of water at 35 ° C; After a few seconds of stirring, the inorganic fiber material (aluminosilicate fibers "Fiberfrax") was mixed in and then vermiculite (Mr.4 Zonolite 0.4 to 1.7 mm) was slowly added at a high mixing speed within 1 min and a further 15 s mixed. The slurry was then precipitated by adding 30 cnr of 10 Joigen Alaufil solution and 10 cnr of 1% surfactant solution (Separan NP-10) with mixing for 10 seconds

the whole thing was in a hand-molded frame 19 x 20 cm for

ρ
poured a total area of 380 cm, then blotting paper

pressed on with a pressure of about 10 g / cm to remove excess water, and finally dried e.g. in a usual dryer for photocopies.

A series of experiments with varying proportions has now been carried out carried out by VemLculit, fiber material and binders. Zuj> i comparison were used in experiments in which either only organic or inorganic binders were used (A or B). The following table shows the quantities the starting materials, the ratio of the two types of binder,

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the possibility of bending around a radius of about 4.5 cm and finally the tensile strength of a 2.5 cm wide strip of the specified thickness before and after firing at 650 ^° C. for 15 minutes including the percentage expansion. a ", half-quantities were used in order to arrive at a half-thickness sheet material. The expiration time, the strength and the strength are therefore about half that of the other tests.

It can be seen from the table that Comparative Experiments A and B were excessively long drain times and poor tensile strength, respectively after firing. Test 14 is also a comparison in which one has extremely low strength noted. Experiments 5, 6 and 7 also do not come under the subject matter of the application and do not have the desired one Flexibility. Experiments 4, 8 and 9 show that the ratio of the two binders to one another is too low. One observes a flexibility corresponding to thinner web material (about 1.5 mm) with a not quite corresponding flexibility due to bending around a radius of 4.5 cm with a larger one Thickness (about 3 mm).

Tabel;

909808/0889

verse . Vermi-Anorg. 15th c: ulit fibers 15th 1 75 25th 2 75 25th 3 60 12 _{) 5} 4th 60 30th 4a 30th 25th co VJl 50 O δ 60 25th co 00 7th 50 25th O 12.5 OO 3 50 30th * «S
O Sat 25th 15th OO 9 50 '25 co 9a 25th 25th 10 50 25th 11 50 25th 12th 50 ¹² J ⁵ 13th 50 25th 13a 25th 25th 19th 50 25th A. 50 50

binder
Org.Anorg,

3.3 6.7

5.0
6.4

8.4

2O ₅ O

0
25jO

5 ₃ O 8.6 10.0

5.0

2.5 5.0

5; 2 14.8

3.0 12 ₃ 0

5.0 2O ₅ O

16.6

4 _; 2 8.3

7 ₅ 9 12.1

4.0 6.1

10.7 14.3

12.5 12.5

13.5 11.5

15.0 10.0

7.5 5.0

5 ^ 0 25j0

Org. Anorg.

1.00

O _; 75 0.50 0.50 0.35 0.25 0.25 0.50 0.50 0.65 0.65 0.75 1.00 1.17 1.50 1 ₃ 5O

unbounded load, flexible expiry time

(a)

10

7 10

21 16 54 35 7 17

28 12 over 7 3 3

> 60 2

= 4.5 cm kg

0.54
0.49
1.08
1.31
0.70
2.06

Ij 12

2.70
1 ₃ 42
2.12

2.20

1.42
ι

0 _; 92

Oj 22

0.11

0 _j0 2

Thickness ( now)
^before after

expansion

2.79 9j78

2.54

1.78
3.05
3.05
2 _; 95
3.05
1.52

1.73
2.67
2 _; 67

2 ^ 79

9.65
9.14

9.53
5.08
8th, 38th

7.62
7.62
4.06
9.40
5.08
7.87

7j87
2j54 9.65
2.54 io 16
1.45 5 _; 08
2 _; 67 10.92

9.91

251

280

228

242

185

175

221

158

150

167

222

19Ü

195 195 280 300 250 309 290 255

ro

03

r = 6 approx

W VJI

(D -i.

¹ OOV »

et 4> 4>

2 ^ B vji

(D

VO

■ si

00

Claims (3)

P a t e entansprüch \\. Expandable web material containing 40 to 75% by weight of non-expanded vermiculite, 15 to 35 % by weight of inorganic fiber material and inorganic binder according to DE-P 24 41 633, characterized in that it contains 25 to 10% of a combination of an organic elastomeric binder and Contains clay as an inorganic binder in a ratio of 0.5 to 1.5. 2. Web material according to claim 1, characterized in that the fiber material is an aluminosilicate is. 3. Web material according to claim 1 or 2, characterized in that the clay is bentonite. 8183 909808/0889 ORiGuMAL INSPECTED