WO2001019744A1

WO2001019744A1 - High temperature resistant saline soluble fibres

Info

Publication number: WO2001019744A1
Application number: PCT/GB2000/003275
Authority: WO
Inventors: Gary Anthony Jubb; Jean-Louis Martin
Original assignee: The Morgan Crucible Company Plc
Priority date: 1999-09-10
Filing date: 2000-08-24
Publication date: 2001-03-22
Also published as: CA2383440C; CZ2002862A3; DE60003569D1; EP1212265A1; ES2202162T3; JP2003509320A; AU769172B2; CZ296627B6; EP1212265B1; AU6713200A; BR0013868B1; PL354487A1; BR0013868A; US6861381B1; CA2383440A1; JP4066138B2; ATE243665T1; DE60003569T2; RU2247085C2; CN1373740A

Abstract

A fibre is disclosed having a maximum use temperature of 1200 °C or more which comprises: SiO2 > 64.25 wt % CaO > 18 wt % MgO < 17 wt % and in which the amount of MgO in mol % is greater than the amount of CaO in mol %. Such fibres have high solubility and low dustiness.

Description

HlSHJEMPERATURF. RESISTANT SALINE SOLUBLE FIBRES

This invention relates to high temperature resistant saline soluble fibres and particularly relates to calcium-magnesium-silicate fibres.

Calcium-magnesium-silicate fibres are known for example from WO89/12032, WO93/15028 and WO94/15883.

WO89/12032 first disclosed a broad class of fire-resistant saline soluble fibres.

WO93/15028 showed that a class of the fibres of WO89/12032 were usable at temperatures up to 1000°C or more.

WO94/15883 showed that some of the fibres of WO93/15028 had higher use temperatures still, of up to 1260°C or more, and indicated that such fibres needed a SiO₂ excess (defined as the amount of SiO₂ remaining after crystallisation of CaO, MgO and any ZrO₂ as silicates) of greater than 21.8mol%.

WO97/16386 while falling in the general class of calcium-magnesium-silicate fibres looked to low calcium fibres to show use temperatures of 1260°C or more.

It is apparent that there are regions of the CaO-MgO-SiO₂ and CaO-MgO-SiO₂-Zrθ2 composition fields within which high temperature performance fibres can be made and other regions where they cannot.

The applicants have now found a new and narrow range of compositions that are usable at temperatures of 1200°C or more and even 1250°C or 1260°C or more, and yet fall outside the scope of WO94/15883 and WO97/16386. These compositions preferably have little or no zirconia. Accordingly the present invention provides a fibre having a maximum use temperature of 1200°C or more in which the amount of MgO in mol% is greater than the amount of CaO in mol % and which comprises :-

SiO₂ >64.25 wt%

CaO >18 wl%

MgO < 17 wt%. However, no claim is made to fibres having a SiO₂ excess as specified of greater than 21.8mol%.

Further features of the invention are apparent from the appended claims.

The excess SiO₂ figure is calculated by treating all of the CaO as being bound as CaO.MgO.2SiO₂; all of the ZrO₂ as being bound as ZrO₂.SiO₂; and the remaining MgO as being bound as MgO.SiO₂. The applicants also assume that any Al₂O₃ crystallises as AI2O3.S1O2. Any remaining SiO₂ is called the excess SiO₂.

The invention is illustrated by way of example in the following description with reference to the drawings in which

Fig 1 is a graph showing linear shrinkage with temperature for blankets comprising the fibres A4-2 and A4-3 of Table 1 below.

Fig. 2 is a graph showing shrinkage through the height of blankets comprising the fibres A4-2 and A4-3 of Table 1 below.

Fig. 3 is a graph showing shrinkage of preforms produced from fibres A4-1 , A4-2 and A4-3 of Table 1 below. Table 1 shows compositions extracted from WO89/12032, WO93/15028, WO94/15883, and WO97/16386 together with A4, a target composition fibre having the composition:-

SiO₂65 wt% CaO 19.5 wt% MgO 15.5 wt%

and A4-1 , A4-2, and A4-3, which are analysed fibre samples.

The fibres extracted from the data of WO89/12032 (referred to as Manville fibres), WO93/15028, WO94/15883, and WO97/16386 (referred to as Unifrax fibres) are those for which the SiO₂ excess as specified is less than than 21.8mol% and for which the amount of MgO in mol% is geater than the amount of CaO in mol%.

A4-1 was produced as bulk fibre; A4-2 was produced as needled blanket having a density of approximately 96 kg.m^"3; and A4-3 was produced as needled blanket having a density of approximately 128 kg.m^"3.

In Table 1 shrinkages are indicated from the documents concerned or, for A4-1, A4-2, and A4-3, from measuring the shrinkage of vacuum formed preforms of the fibres concerned.

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It can be seen that the fibres according to the present invention show lower shrinkage at 1260°C than do the extracted fibres other than fibre Unifrax 42 which has a radically different composition.

In Figs. 1-3, graphs show the shrinkage characteristics of the fibres A4-1, A4-2, and A4-3 after 24 hours exposure to the indicated temperatures, it can be seen that the fibres are readily usable at temperatures of 1200°C or more.

Table 2 below shows the results of solubility tests on the fibres in physiological saline solution indicating mat the fibres are soluble in body fluids. (See WO94/15883 for a discussion of methods of measuring solubility). Pairs of results are indicated for separate tests on each sample as is a mean total solubility.

A typical range of compositions for fibres of the present invention would be

SiO₂65 ±0.5 wt% CaO 20 ± 0.5 wt% MgO 15 ± 0.5 wt%. Further tests were made on fibres having the inventive composition of SiO₂65%, CaO 19.5%, MgO 15.5% in comparison with Superwool 607™, a fibre having the nominal composition (by weight) of SiO₂65%, CaO 29.5%, MgO 5.5%, and Al₂O₃ <1% ; Superwool 612™, a fibre having the nominal composition (by weight) of SiO₂ 64.5%, CaO 17%, MgO 13.5%, ZrO₂5%; and refractory ceramic fibre having the nominal composition SiO₂ 56%, Al₂O₃ 44%.

The first test was aimed at indicating the amount of dust that might be released on handling. The test comprised the determination of the amount of dust present in a sample of blanket made from the respective fibres. The samples of blanket were vibrated on a Fritsch Analysette type 3010 vibratory sieve shaker, which was set for a frequency of 3000Hz and vertical amplitude of 0.5mm. The apparatus was equipped with a 1.6mm sieve and a pan. In the test method a sample of blanket 135mm x 135mm was placed on the sieve and vibrated for 10 minutes. The material collected in the pan was weighed and expressed as a percentage of the original weight of the sample. The results were as indicated below:-

Fibre Material Percent dust released

Superwool 607™ 0.16%

Inventive material 0.18%

Refractory ceramic fibre 0.25%

Superwool 612™ 0.36%

From this it can be seen that the inventive fibre is of comparable low dustiness to Superwool 607™.

The second test made was to look to the shrinkage behaviour of blanket formed from the inventive fibre and the two Superwool™ fibres at high temperatures. Samples of blanket were exposed to specified temperatures for 24 hour periods and their linear shrinkage measured. The results are indicated in Table 3 below:-

This shows that the inventive fibre is comparable in performance with both Superwool™ fibres up to 1200°C. At 1250°C the Superwool 607™ fibre shows a shrinkage of 4.8% (which would be considered as too high a shrinkage for most applications). At 1300°C the inventive fibre while still showing a high shrinkage of 4.2% is the best of the three fibres tested.

A further series of tests were made to produce fibres on a production scale and the compositions of fibres obtained were as set out in Table 4 below. All showed low shrinkage at 1250°C (shrinkages were measured by different methods to Table 1 and are not directly comparable). In combination with the results of Table 1, this shows samples of usable characteristics having compositions consisting essentially of (in wt%)

CaO 18.7 to 20.2

MgO 14.47 to 15.9

SiO₂ 64.5 to 65.1

Al₂O₃ 0 to 0.56

The fibres of the present invention therefore have a high solubility (desired to permit fibres to be cleared from the body quickly); a low dustiness (desired to reduce the amount of fibre that can be inhaled); and good high temperature characteristics. cn

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Claims

1. A fibre having a maximum use temperature of 1200°C or more which comprises:

SiO₂ >64.25 wt%

CaO >18 wt%

MgO < 17 wt% and in which the amount of MgO in mol% is greater than the amount of CaO in mol % and in which the SiO₂ excess as specified is no greater than 21.8mol%..

2. A fibre as claimed in claim 1 and comprising:-

CaO <21 wt%.

3. A fibre as claimed in claim 2 and comprising:-

CaO <20.5 wt%.

4. A fibre as claimed in any of claims 1 to 3 and comprising:-

CaO >19 wt%.

5. A fibre as claimed in claim 4 and comprising:-

CaO > 19.5 wt%

6. A fibre as claimed in any of claims 1 to 4 and comprising:-

MgO > 14.25 wt %.

7. A fibre as claimed in claim 6 and comprising: -

MgO > 14.75 wt %.

8. A fibre as claimed in claim 7 and comprising:-

MgO> 15.25 wt%.

9. A fibre as claimed in any preceding claim and comprising:-

MgO<16wt%.

10. A fibre as claimed in any preceding claim and comprising:-

SiO₂65 ± 0.5 wt% CaO 20 ±0.5wt% MgO15±0.5wt%.

11. A fibre as claimed in any of claims 1 to 9 and comprising:-

SiO₂64.5 - 64.7 wt% CaO 19.5- 20.2 wt% MgO 15.5- 15.6 wt%.

12. A fibre as claimed in any preceding claim and comprising: -

SiO₂ about 65 wt% CaO about 19.5 wt% MgO about 15.5 wt%.

13. A fibre as claimed in any preceding claim and consisting essentially of:-

CaO 18.7to20.2wt% MgO 14.47 to 15.9wt% SiO₂ 64.5to65.1wt% Al₂O₃ 0to0.56wt%