CA1298323C - Hard setting refractory composition - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

Novel compositions are disclosed for the manufacture of gunning mixes and strong castable products for use as monolithic refractory and construction materials which may contain no lime bearing cements. Bonding is based on the setting reaction of fumed silica with an alkali metal silicate preferably a particulate sodium or potassium silicate that slowly dissolves in water such as an anhydrous sodium silicate of Si02:Na20 molar ratio of 1:1 to 4:1; or an anhydrated potassium silicate having an Si02:K20 molar ratio of 3:1, or a hydrated sodium silicate having an Si02:Na20 molar ratio of 3:1. Setting and mechanical characteristics allow this class of castable and gun mixes to be placed more rapidly into service since the time required for curing is much less. Although initial set strengths are not as high as those of conventional castables, very high strengths can be made to occur shortly after setting by heating. The addition of sodium hexametaphosphate was found to be highly beneficial to working and handling characteristics.

Description

~2~33~3 HARD SETTING REFRACTORY COMPOSITION

BACKGROUND OF THE INVENTION

The invention relates to hard setting refractory compositions and especially to rapid hard setting castable refractory c~mpositions comprising fumed silica and a refractory material, such as one containing alumina, which when mixed with water will set to a hard mass at normal outdoor temperatures without any calcareous cementious material being present in the composition.
Calcareous cements that contain fumed silica and are rapid setting are known as shown in Miller et al Patent No. 4,501,830. Also, Patent No. 4,506,025 discloses a castable silica brick composition containing fumed silica, silica and portland cement. This composition is relatively slow setting and contains undesirable calcium oxide compounds. Japanese Patent No. 1981-78476 shows a similar castable composition based on the coagulation of superfine silica powder with the Ca ions of Portland cement.
U.S. Patent No. 3,121,641 discloses a castable composition containing alumina and fumed silica and U.S.
Patent No. 3,067,050 discloses a gunning mixture containing alumina and fumed silica. However, these compositions do not set quickly to a hard set, and must be given a lengthy curing and then fired to obtain suitable strength and hardness.
SUMMARY OF THE INVENTION

The present invention is based on my discovery that alkali metal silicates with fumed silica and refractory material when mixed with water will set to a hard mass at normal atmospheric temperatures and even lower. The alkali metal silicates act as active reagents or accelerators to initiate and speed up the hardening action of the fumed silica in such compositions. They are effective in such small quantities as 0.2-5% of the mixture.
The preferred alkali metal silicates for use in casting compositions and other purposes that require 12g~323 more time than flash setting are the particulate alkali metal silicates that have a rate of solution in water less than that of hydrated sodium silicate having a molar ratio of SiO2:Na20 of 1:1. This is because the setting time depends upon the rate of solubility. The anhydrous alkali metal silicates dissolve with more difficulty than the hydrated silicates and the silicates containing more alkali metal in the molecule dissolve more readily.
Suitable alkali metal silicates that do not produce a very rapid or flash setting composition and that can be uniformly mixed before setting include the particulate anhydrous sodium silicates having a molar ratio of SiO2:Na20 of at least 1 to 1, preferably 2:1 to 4:1 particulate hydrated sodium silicates having a molar ratio of SiO2:Na20 of at least 3:1, preferably 3:1 to 4:1, and particulate anhydrous potassium silicate having a molar ratio of SiO2:K20 of at least 3:1.
Compositions containing fumed silica and liquid 2C sodium silicates or hydrated sodium silicates having a molar ratio of SiO2:Na20 of 1:1 have a very rapid or flash set and are impractical for most uses since they cannot be uniformly mixed before setting, but they can be used for filling holes, patching and the like.
The binding mechanism of alkali metal silicates with fumed silica can be employed with a great variety of formulations, preferably those containing alumina such as bauxites, and high alumina materials. Other material used in refractory applications such as calcined clay, silicon carbide, spinel, and zircon may be used. This includes formulations for placement by gunning and shotcreting application as well as by casting.
One advantage of this invention is that it is not necessary to use calcareous cements or lime.
It is also an object of this invention to provide refractory cast products that can be installed with lesser concern for curing procedures and put into service soon after hardening.
It is a further object of this invention to provide more predictable and reliable properties than is often the case with complex calcium aluminate cement systems.
A preferred composition to harden both cast and gunning materials comprises fumed silica in from 3-30%

~zg~323 of the total refractory composition, powdered anhydrous sodium silicate with a silica to soda ratio of 1:1 to 4:1 in the range of 0.2 - 5% of the total mix, and a major amount of refractory aggregate comprising alumina. When the anhydrous sodium silicate is replaced with hydrated sodium silicate the molar ratio of Si02:Na20 for similar results should be 3:1 to 4:1.
With anhydrous potassium silicate the molar ratio of Si02:X20 should be at least 3:1.
With refractory compositions comprising a refractory aggregate, fumed silica and an alkali metal silicate, a minor amount of an alkali metal phosphate (as low as 1/2% and even less) is helpful in giving improved flow characteristics to the casting com osition. For example, polyphosphates such as sodium hexametaphosphate are helpful in approximately 0.1 to 1.0% by weight of the total composition.
Castables and gunning formulations may be made without the inclusion of calcarious cementitious components using fumed silica as the sole binder. This is made feasible by my discovery that the addition of alkali metal silicate reagents to the fumed silica promotes a hardening reaction even without CaO similar to that common to Portland cement products. For casting, the dry mix is tempered with clean water and can be poured and vibrated into place, or troweled, in the normal manner. However, since these are relatively dense due to the low water requirement, they must be mixed a few minutes longer and are somewhat stickier on pouring. When placed they should not be covered, misted with water, sealed, or in any way prevented from drying out. Gunning requires no special procedures. After the forms are stripped the cast or gunned products can be allowed to dry out, even by the application of mild heat, and allowed to set. Shortly after setting these products, unlike Portland cement products, can be fired or otherwise uniformly exposed to high heat without harm to the products.

DESGRIPTION OF THE PREFERRED EMBODIMENT

Several examples of formulations which embody this invention are given in the examples to follow:

lZ983~3 Example 1 A refractory castable was formulated as follows: ~_ 35.4% Mulcoa 60 -4 mesh 26.6% Bauxite -10 mesh 17.7~ ~used alumina -325 mesh 8.9~ Calcined alumina -325 mesh 11.1~ Fumed silica (spherical particles average 0.15 microns) 0.3% Sodium Silicate -200 mesh (Portil N) 0.1% Sodium hexametaphosphate Mulcoa 60 is a calcined kaolin product of the C. E.
Minerals Company containing about 60% alumina. The bauxite may be South American, Chinese, or a blend of calcined bauxites.
The sodium silicate of the above example (Portil N) was in the weight ratio of SiO2 to Na20 of 3.22:1, and i8 a hydrated sodium silicate of about 14% water of hydration. Henkel KGaA in Germany markets Portil N.
The 0.3% level of sodium silicate allows adequate workinq time to cast the material. Larger grain size reagents having this ratio are also available.
Philadelphia Quartz Company's SS-20 and SS-65 are anhydrous sodium silicates of SiO2:Na20 ratio of 3.2:1 that can be used in higher levels of sodium silicate because of their lower reactivity. In combination or singly the range of silicate powders can preferably span from .2% to 1.5~ of castables and up to 5% of gun mixes. The limitation on the latter is to avoid a high level of alkali inclusion and a rapidity of set which can complicate clean up procedures.
To mix, 4 to 4 1/2% water can be put into the mixer first or added to the dry castable. A minimum of 5 minutes mixing time is used to develop a casting consistency. Internal and external vibrators are both useful for good placement. ~owever, the high densities obtained with these low water requirements make external vibration more effective when practical. Shortly after the material sets, normally within an hour, forms can usually be removed. At this point it can be gently heated or placed in an oven for drying and then uniformly heated at high temperatures and even fired.
Strong direct flames should be avoided until considerable drying has taken place, or until 48 hours have elapsed if no other source of heat has been used.
* Trade-mark .

~291~3Z3 Example 2 A series of castables wexe formulated as follows:
_ ~ 3 4_ Mulcoa 47 9 lbs 9 lbs 9 lbs 9 lbs -10 mesh Fused alumina 4 lbs 4 lbs 4 lbs 4 lbs -325 mesh Fumed silica 2 lbs 2 lbs 2 lbs 2 lbs 10 Calcined alumina 3 lbs 3 lbs 3 lbs 3 lbs -325 mesh Raw kyanite 2 lbs 2 lbs 2 lbs 2 lbs -35 mesh Sodium silicate 1 oz 1 oz 1 oz 1 oz -200 mesh Sodium hexameta~ 1/4 oz 1/2 oz 1 oz 2 oz phosphate Water 19 oz 19 oz 19 oz 19 oz 20 Physical data 1000F:
Bulk Density 150 153 146 147 lbs/cu ft Cold crush strength 3500 3800 2800 3400 psi This data shows the effect of varying sodium hexametaphosphate (SHMP). The level of Test 2 was optimal, about 0.2%. The sodium silicate in all the above tests was in powder form and had a weight ratio of SiO2 to Na20 of approximately 3.22 to 1.
Example 3 A blend was made of 9 lbs. of calcined Missouri flint clay, -1/16 inch, 4 lbs. of -325 mesh fused alumina fines, 2 lbs. of fumed silica, 2 lbs. of -35 mesh raw kyanite, and 1/2 oz. SHMP. To this was added several levels of -200 mesh hydrated sodium silicate (Portil N), of a weight ratio of Sio2:Na20 of 3.22:1 (approximate molar rate of 3:1)). All were cast with 19-20 oz. water (about 6%). Results were as follows:

Wt Portil N %Work Time1000F Cold Crush oz min Strenqth ~si 0 0No set ---1/2 0.16Skin, no hard set ---3/4 0.23130 ---1 0.3118 3800 2 0.628 6400 3 0.947 7400 4 1.25 Flash set ---The flash set can be avoided by adding most of the Portil N at the end of the mix just prior to casting.
Coarser sized silicates such as Philadelphia Quartz' 129~3323 SS-20 and SS-65 can be used initially but preferably not above 1.5% in most cases or added just prior to casting~ Levels above 0.5% of any of the powders are not recommended as initial blends with formulations of 85% alumina and above.
Formulations containing graphite, silicon carbide, chromium oxide, ~irconia, and zircon have all been made and are usable with this method of bonding. Silicon metal additions are useful with graphite and silicon carbide to promote higher strengths and oxidation resistance. However, the use of powdered metals and even iron ball milled raw materials can produce hydrogen gas in amounts sufficient to be of concern.
Example 4 The following formulation is an example of a gunning mix using this novel bonding system.
15 parts Calcined Bauxite 1/4 by 1/16 inch 65 parts Calcined Bauxite -1/16 inch 5 parts Fumed silica 10 parts Raw kyanite -100 mesh 205 parts Ball clay 1 part Sodium silicate (Portil N) This product gunned with little rebound or dusting and required less water than conventional gunning materials. A higher level of silicate accelerator is used than with ordinary castables to promote fast hardening to prevent any tendency to slump. The practical limit is at about 5% to avoid excessive sodium content (a flux). SHMP is not needed in the gunning mixes. Many other aggregates can be used, such as calcined clays, fused and tabular aluminas, etc.
Additives such as carbons, silicon carbide, chrome oxide, zirconia and zircon can be advantageous in this systemO Metal powders such as silicon are beneficial to propertiès but may produce hydrogen.
The level of fumed silica was also investigated. A
practical lower limit of 5% produces good strengths and reasonably low water requirements, and is preferred for high alumina castables, and in gun mixes (where higher levels are dust producing). The 10% level has been found overall to be adequate and optimal in most cases for castables. Levels of 15-25% impart an undesirable stickiness and water requirements climb. Silica contents may be rather high at the higher levels.

lZ98323 However, the entire range from about 3~ to 30~ fumed silica is viable for this bonding mechanism.
Fine powdered sodium silicates most useful have roughly 63~ Sio2, 19% Na20, and 18~ H20 corresponding to a molar ratio of Si02:Na20 of approximately 3:1. The two coarser silicates, namely Philadelphia Quartz Company's SS-20 and SS-65, are essentially anhydrous, containing roughly 75~ Si02 and 23~ Na20. As stated, these also work but preferably at higher concentration levels.
Compositions were tested with potassium silicate molar ratio of Si02:K20 of about 3:1 (Portil Potassium) from Henkel KG2A*containing 56~ Si02, 28~ K20, and 16~
~2) In this hydrated form this reagent is too readily soluble and caused an almost instant setting reaction.
This material was dehydrated by calcining at about 1300F for about 18 hours and grinding to -65 mesh.
This material was substantially free of all water. This treatment produced a successful result, as described in the following example.
Example 5 A blend of 12 lbs. of -1/4 inch and down of Mulcoa 47 brand calcined clay, 2 lbs. of fumed silica, 4 lbs.
of -325 alumina fines, 2 lbs. of -100 mesh kyanite, 1/2 oz. of SHMP, and 1 1/4 oz. of dehydrated potassium silicate, -65 mesh, was mixed with 1 lb. 4 oz. water.
This was a good working castable. The working time prior to an initial set was about 8 minutes, somewhat less than that obtained with the sodium compound. Dried cold crush strengths after about 20 hours at 220F
averaged 3800 psi.
Anhydrous potassium silicate of a weight ratio of Si02 to K20 of 2:1 (molar ratio of 3:1) is manufactured by the Philadelphia Quartz Company as Kasil SS Powder, and gives the same result~ as the above dehydrated material.
The following shows the results of studies on the effect of reagent ratios (and corresponding molar ratios) of Si02:Na20 and Si02:K20 with and without hydration of the silicates on the working time for mixing with water to obtain a set.
Calcined clay (MULCOA 47) 3x8 mesh 7 lbs.
Calcined clay (MULCOA 47) -8 mesh 5 lbs.
Fumed Silica 2 lbs.
Fused alumina fines -325 mesh 4 lbs.
Raw kyanite -100 mesh 2 lbs.
Sodium hexametaphosphate1/2 oz.
* Trade-mark `

-3;~3 To this was added several alkali silicate additions as shown in the following table with differing SiO2:Na20 and K20 ratios both hydrated and anhydrous. The results are indicated.

Wt. Working Silicate Ratio Addition Hydrate Time Cold Crush (after 230F) Sodium 3.2:1 1 ounce Yes 30 min. 3800 psi 3.2:1 3 ounces No 60 min. 7000 psi 2:1 1 ounce Yes Flash set --2:1 1 ounce No 90 min. 6300 psi 2:1 2 ounces No 12 min. 7700 psi 1:1 1 ounce Yes Flash set --1:1 2 ounces No 15 min. 2200 psi Potassium 2:1 -150 32 grams Yes Flash set --mesh 2:1 -40 1 ounce Yes 4 min. 3650 psi mesh 2:1 34 grams No 8 min. 3700 psi 2.5:1 1 ounce No 90 min. 3700 psi 2.5:1 2 ounces No 20 min. 6700 psi 2.5:1 4 ounces No 5 min. 6200 psi All ratios tested can work. In the hydrated form the lower ratios materials would set too rapidly for casting. They could all be used for gunning. All of the castables were tested with about 6% water. The silicates were all in powder form.
The percent amounts given in the specification and claims are all weight percents.
The mesh amounts are Tyler screen sizes.
The ratios given in the specification and claims are molar ratios except where specifically indicated as weight ratios. The weight and molar ratios for the sodium silicate are substantially the same and the 2:1 weight ratio for the potassium silicate is approximately a 3:1 molar ratio.
The term fumed silica is also known in the trade as volatilized silica, arc silica and silica fume. A
typical analysis including particle size of silica fume is shown in U.S. Patent No. 4,310,4B6.

Claims (7)

1. A workable binder which when mixed with water can be poured or vibrated in place and will set to a hard mass at normal atmospheric temperatures comprising a fumed silica binding agent, an alkali metal phosphate tempering agent, and a particulate alkali metal silicate hardening agent, said alkali metal silicate being selected from a group consisting of anhydrous sodium silicate having a molar ratio of SiO2:Na2O of 1:1 to 4:1, hydrated sodium silicate having a molar ratio of SiO2:Na2O of 3:1 to 4:1, an anhydrous potassium silicate having a molar ratio of SiO2:K2O of at least 3:1, and mixtures thereof.

2. A workable binder in accordance with claim 1 wherein:
the ratio of fumed silica binding agent to alkali metal silicate hardening agent ranges from about 32:1 to about 5:1, and the ratio of fumed silica binding agent to alkali metal phosphate tempering agent ranges from about 30:1 to about 300:1.

3. A workable binder in accordance with claim 1 wherein:
said alkali metal silicate accelerating and hardening agent is a mixture of said anhydrous sodium silicate and said sodium silicate hydrate.

4. A workable binder for use in conjunction with aggregate and filler material to produce a hard setting castable composition, said binder comprising a binding agent of silica fume, a hardening agent of alkali metal silicate and a tempering agent of alkali metal phosphate, said agents comprising a mixture in the following dry weight proportions on a basis of 100 parts of said binding agent; about 2 to about 25 parts of said hardening agent, and about 1 to about 3 parts of said tempering agent.

5. A workable binder in accordance with claim 4 wherein:
said alkali metal silicate is anhydrous and said 2 to 25 parts of said hardening agent are comprised of about 10 to about 25 parts of anhydrous alkali metal silicates.

6. A workable binder in accordance with claim 4 wherein:
said alkali metal silicate is hydrated and said 2 to 25 parts of said hardening agent are comprised of about 2 to about 10 parts of hydrated alkali metal silicate.

7. A workable binder in accordance with claim 4 wherein:
said alkali metal silicate is a combination of anhydrous and hydrated alkali metal silicate, said 2 to 25 parts of said hardening agent being comprised of about 1 to about 4 parts hydrated alkali metal silicate and about 4 to about 8 parts anhydrous alkali metal silicate.