FR2486956A1 - Stable alkali silicate soln. of high silica content - obtd. by treating soln. with strong mineral acid - Google Patents

Abstract

Stable alkali silicate solution of high SiO2/R2O ratio is obtd. by treating a soln. of alkali silicate with a strong mineral acid, esp. phosphoric acid. The ratio achieved is at least 3.3 and at least 3.9, and contains 3-30(10-20)% SiO2. Used for ground consolidation. Improved stability of soln. can be achieved at the gel point with a high concn. of SiO2 and a low concn. of metal oxidn.

Description

SILICATE SOLUTION WITH HIGH MOLAR RATIO, OBTAINING
AND APPLICATION IN PARTICULAR TO SOIL CONSOLIDATION
The present invention relates to a solution of silicates with a high molar ratio, to obtaining it, and to its application in particular to soil consolidation.

 It has been known for a long time that it has been proposed to obtain high-ratio silicates by contacting a silicate solution with a strong acid cation exchange resin as in US Pat. No. 2,244,325, or by enrichment of A silicate solution with a solution of silicic acid horn in US Pat. No. 3,533,816. Generally described in French Patent 1,338,872 a process for the production of silicates which can be of high ratio per reaction. of a freshly prepared monomeric silicic acid organosol and a finely divided metal hydroxide so that the pH of the medium becomes instantaneously greater than 7, which causes the formation of a gel.

 However, in some applications, as in the case of soil consolidation, it is desired to cause gelling, but only at the time of use, while using a high silica content product. This is why, for example, in FR 2,015,165 it is claimed to use a mixture formed by a dispersion and comprising a phase in solution constituted by an aqueous solution of alkali silicate and an aqueous phase constituted by an aqueous dispersion of silica - colloidal, so as to reach a SiO2 / Na2O ratio as high as possible.

 But we see that on the one hand it is necessary to appeal to two different compositions (a solution and a dispersion) and that one is always dependent on the requirements of the silicate solution which one knows that it is necessary to reduce the solids content in order to maintain its stability by increasing the molar ratio SiO 2 / Na 2 O (FR 2 015 165 p 5 lines 12-15).

 The problem is then to produce stable solutions of silicate ratio as high as possible.

 It has thus already been claimed in DE-AS 1 667 538 stable aqueous silicate solutions of molar ratio SiO2 / alkali metal oxide between 4.5 / 1 and 9/1 by using as stabilizer an ammonium derivative quaternary. But we can realize that this is not a simple solution.

 It is also known that many studies have been made on silicate solutions with a molar ratio of 5iO 2 / Na 2 O - see in particular Tne Chemistry of Silica Ralph K. John Wiley Sounds 1979 - To obtain silicate solutions, silicate is generally produced. glassy SiO2 / Na2O molar ratio of between 1.6 and 3.9, which is dissolved. The concentration of silica in the solution is even higher than the molar ratio is lower (see page 119 of the aforementioned work).

 It is also possible to directly obtain silicate solutions with a molar ratio of between 2.0 and 2.5 by autoclavable sand attack with a sodium hydroxide solution.

 The problem is then to raise the molar ratio of the solution because in particular in the case of soil consolidation, it is necessary both to provide as much silica as possible, and the least possible metal oxide.

 However, it has been observed that serious difficulties are encountered when it is desired to obtain stable solutions rich in silicas. In particular, the formation of gel or at least a clear instability with customary acidifying agents such as IonO 3, HCl, CO 2, boric acid or organic acids such as formic, acetic, propionic, succinic, glutaric and adipic acid is observed in particular. , acrylic or polyacrylic.

 However, it has now been found, and this is the object of the present invention, that stable solutions of alkali silicates can be obtained by a process consisting in treating an alkali silicate solution with a strong acid. mineral.

 The alkali silicate solution, as previously mentioned, can be either a solution obtained from vitreous silicate, or directly by sodium attack.

The strong mineral acid may be, for example, sulfuric acid, but according to a preferred embodiment of the present invention, phosphoric acid is used. It is observed that with phosphoric acid it is possible to obtain a better stability and in particular to obtain solutions of molar ratios.
SiO2 / higher metal oxides.

 This is an entirely unexpected and unpredictable effect on the part of those skilled in the art since the percentage of cation is substantially the same, to the nearest measurement errors, between the sulfuric acid and the sulfuric acid. Phosphoric acid.

 The silicates according to the invention optionally comprise sodium silicates, but also potassium and lithium silicates.

According to the present invention, the starting silicate has a molar ratio Bm = SiO 2 of between 2 and 4 and the final product
Na O
2 a ratio Rm of at least 3.3 and advantageously at least 3.9.

 But as said before the stability of the silicate solutions depends on the concentration of solids, or dry extracts. This is expressed in% by weight of SiO 2 depends on the SiO 2 / Na 2 O molar ratio.

 The concentrations of the starting silicate solutions can vary within wide limits but are of the order of 15 to 30% by weight of SiO 2.

 The concentration of phosphoric acid is between 1 and 87 X.

 The reaction temperature is between 10 and 950C, and advantageously between 20 and 40oC.

 Moreover, it is observed that, unlike what happens when a silicate solution is reacted with another acid, the solutions obtained are stable, that is to say that their viscosity remains substantially constant with time.

 This is of course a significant advantage and makes them usable in all the uses where, with a silicate, it is desired to add a lot of silica, relative to the amount of sodium oxide, which is to be avoided in the case the sealing of the soil.

 However, it has been observed that the silicate solutions according to the invention are perfectly suited to this type of application, and make it possible in particular to prepare ready-to-use and transportable solutions. It is indeed unthinkable to carry out on the spot an acidification reaction with a strong acid.

 In particular they are suitable for formulations containing% SiO 2 between 3 and 10% and in particular 10 to 20%.

 But of course this application is not limited to the product according to the invention.

 But the present invention will be more easily understood using the following examples given for illustrative purposes, but in no way limiting.

1st serine of examples
These examples are intended to study comparatively the action of various acid solutions on the same alkali silicate solution under the same operating conditions. The alkali silicate solution consists of a solution containing 266 g / l of SiO 2 and 74.1 g / l of Na 2 O, which corresponds to a silicate with a molar ratio Rm equal to 3.5.

 The reaction temperature is 200C for all the examples.

 a) In a 5 liter reactor containing 3855 g of the silicate solution, 79.7 g of orthophosphoric acid at 85 × expressed in H 3 PO 4 diluted in 1133 g of deionized water are poured in over 5 minutes to obtain a silicate of ratio Rm equal to 4.4.

Under the same operating conditions phosphoric acid is replaced by the following mineral and organic acids: (*)
Observations immediate precipitation
H2S04 precipitation after a time
relatively short HN03 immediate precipitation
Carbonic acid (C02 gel bubbling on the surface
in silicate)

<tb> Organic <SEP> acids <SEP> 1
<tb> Acid <SEP> acrylic <SEP> and <SEP> polyacrylamide <SEP> formation <SEP> of <SEP> lumps <SEP>
<Tb>
It is thus seen that only phosphoric acid conducts under these conditions to a stable solution but that a positive effect of sulfuric acid is noted.

(*) the solutions of the various acids used have the same normality
that the H3P04 uses.

2nd series of examples
In this series of examples is carried out according to the preferred embodiment of the invention by varying the temperature and the molar ratio of the silicate.

 The operating conditions and the results are summarized in the table below. These results also concern the application in soil consolidation.

In this table: grouts at 10% Z and 14% SiO2 correspond to the following composition by weight

<tb> SiO2 <SEP>: <SEP> 10 <SEP>% <SEP>: <SEP> 14 <SEP>%
<tb> Silicate <SEP> Rm <SEP> = <SEP> 4,4 <SEP>: <SEP> 50,2 <SEP>: <SEP> 70,3
<tb>: <SEP> Hardener <SEP>: <SEP> 3.9 <SEP> 5.5 <SEP>:
<tb>: <SEP> Water <SEP>. <SEP> 45.9 <SEP>: <SEP> 24.2
<tb><SEP> 100.0 <SEP>: <SEP> 100.0 <SEP>: <SEP>
<Tb>
CNT = theoretical neutralization coefficient of about 0.6
Hardener = molecular weight 181
succinate mixture
methyl glutarate
Adipate and ethyl reactivity: represented by the setting time
for SiO 2 = 10 Z 58 min.

 "" = 14% 22 min.

 syneresis: liquid expelled by the gel 15 days after setting.

 These examples thus illustrate the remarkable behavior of silicates according to the invention in soil consolidation.

 The setting time is conventionally defined as the time between the instant of the mixing of the 3 components and the moment when the grout becomes sufficiently rigid (viscosity increase) to no longer flow when the mixing vessel is inclined until the horizontal.

 The results of these tests are summarized in the tables below.

TABLE I
ANALYSIS OF THE SILICATE OF START
TEMPERATURE OF THE OPERATION

<tb> Silicate <SEP> of <SEP> departure
<tb> Analysis
<tb> Reference <SEP> Report <SEP>% <SEP>% <SEP> Temp.
<Tb>

R
<tb> silicate <SEP> theoretical <SEP> SiO2 <SEP> Na2O <SEP> Oper. <SEP> C
<tb> Silicate <SEP> 2.6 <SEP> 2.69 <SEP> 31.5 <SEP> 11.7 <SEP>
<tb>: <SEP> 1 <SEP>: <SEP> 2,6 <SEP>: <SEP> 2,69 <SEP>: <SEP> 31,5 <SEP>: <SEP> 11,7 <SEP >: <SEP> 20
<tb>: <SEP> 2 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 40
<tb>: <SEP> 1 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 60
<tb>: <SEP> 2 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 20
<tb> 3 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 40
<tb> 1 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 60
<tb>: <SEP> 1 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 20
<tb>: <SEP> 4 <SEP>: <SEP><SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 40
<tb> 2 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 60
<tb>: <SEP> 3.3 <SEP>: <SEP> 3.59 <SEP>;<SEP> 26.6 <SEP>: <SEP> 7.41 <SEP>: <SEP>
<tb>: <SEP> 2 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 20
<tb>: <SEP> 5 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 40
<tb> 3 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 60
<tb>: <SEP> 1 <SEP>: <SEP>"<SEP>"<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 20
<tb>: <SEP> 6 <SEP>: <SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP>"<SEP>:<SEP> 40 <SEP >: <SEP>
<tb> 4 <SEP>"<SEP>"<SEP>"<SEP>"<SEP> 60
<tb> 3.9 <SEP>: <SEP> 4.03 <SEP>: <SEP> 23.7 <SEP>: <SEP> 5.88 <SEP>: <SEP>
TABLE II
ANALYSIS OF THE ARRIVAL SILICATE
AND VISCOSITY AT 24 HOURS AND 3 MONTHS

<tb>: <SEP> Analysis <SEP> silicate <SEP>: <SEP> Viscosity <SEP> in <SEP> mPa / s
<tb>: <SEP> of arrival <SEP> Rheomat <SEP> 30 <SEP> = <SEP> 30
<tb>: <SEP> R <SEP>: <SEP> Reference <SEP>: <SEP> Z <SEP>: <SEP> Z <SEP><SEP>:<SEP> Z <SEP><SEP>:<SEP><SEP><SEP>:<SEP> to
<tb>: <SEP>: <SEP> silicate <SEP> SiO2 <SEP> Na20 <SEP>: <SEP> Na3P04 <SEP>: <SEP> 24h00 <SEP>: <SEP> 3 <SEP> months
<tb>: <SEP> - <SEP>: <SEP> Silicate <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> 286 <SEP >: <SEP> 297
<tb>: <SEP> 3.38 <SEP>: <SEP> 1 <SEP>: <SEP> 24.9 <SEP>: <SEP> 7.37 <SEP>: <SEP> 3.52 <SEP >: <SEP> 97 <SEP>: <SEP> 107
<tb>: <SEP> 3.36 <SEP>: <SEP> 2 <SEP>: <SEP> 25.2 <SEP>: <SEP> 7.50 <SEP>: <SEP> 3.54 <SEP >: <SEP> 95 <SEP>: <SEP> 109 <SEP>:
<tb>: <SEP> 3.35 <SEP>: <SEP> 1 <SEP>: <SEP> 25.2 <SEP>: <SEP> 7.52 <SEP>: <SEP> 3.50 <SEP >: <SEP> 95 <SEP>: <SEP> 110 <SEP>
<tb>: <SEP> 3.71 <SEP>: <SEP> 2 <SEP>: <SEP> 22.2 <SEP>: <SEP> 5.98 <SEP>: <SEP> 4.20 <SEP >: <SEP> 61 <SEP>: <SEP> 58 <SEP>:
<tb><SEP> 3.74 <SEP> 3 <SEP>: <SEP> 22.3 <SEP>: <SEP> 5.96 <SEP>: <SEP> 4.40 <SEP>: <SEP> 53 <SEP>: <SEP> 59
<tb>: <SEP> 3.66 <SEP>: <SEP> 1 <SEP>: <SEP> 22.3 <SEP>: <SEP> 6.05 <SEP>: <SEQ> 4.28 <SEP >: <SEP> 62 <SEP>: <SEP> 60
<tb>: <SEP> 4.27 <SEP>: <SEP> 1 <SEP>: <SEP> 19.1 <SEP>: <SEP> 4.47 <SEP>: <SEP> 4.55 <SEP >: <SEP> 36 <SEP>: <SEP> 38
<tb><SEP> 4.11 <SEP>: <SEP> 4 <SEP>: <SEP> 19.2 <SEP>: <SEP> 4.67 <SEP>: <SEP> 4.50 <SEP> : <SEP> 57 <SEP>: <SEP> 39
<tb>: <SEP> 4.20 <SEP>: <SEP> 2 <SEP>: <SEP> 19.3 <SEP>: <SEP> 4.60 <SEP>: <SEP> 4.50 <SEP >: <SEP> 44 <SEP>: <SEP> 42 <SEP>:
<tb><SEP> - <SEP>;<SEP> - <SEP> - <SEP> - <SEP> 62 <SEP> 69
<tb>: <SEP> 3.93 <SEP>: <SEP> 2 <SEP>: <SEP> 23.3 <SEP>: <SEP> 5.93 <SEP>: <SEP> 1.11 <SEP >: <SEP> 51 <SEP>: <SEP> 55 <SEP>:
<tb>: <SEP> 3.90 <SEP>: <SEP> 5 <SEP>: <SEP> 23.5 <SEP>: <SEP> 6.03 <SEP>: <SEP> 1.06 <SEP >: <SEP> 42 <SEP>: <SEP> 44
<tb>: <SEP> 3.95 <SEP>: <SEP> 3 <SEP>: <SEP> 23.4 <SEP>: <SEP> 5.92 <SEP>: <SEP> 1.11 <SEP > 57 <SEP>: <SEP> 56
<tb>: <SEP> 4.55 <SEP>: <SEP> 1 <SEP>: <SEP> 20.2 <SEP>: <SEP> 4.44 <SEP>: <SEP> 2.08 <SEP >: <SEP> 121 <SEP>: <SEP> 119
<tb>: <SEP> 4.41 <SEP>: <SEP> 6 <SEP>: <SEP> 19.9 <SEP>: <SEP> 4.51 <SEP>: <SEP> 2.08 <SEP >: <SEP> 140 <SEP>: <SEP> (*) <SEP>
<tb>: <SEP> 4.42 <SEP>: <SEP> 4 <SEP>: <SEP> 20.1 <SEP>: <SEP> 4.55 <SEP>: <SEP> 1.97 <SEP >: <SEP> 102 <SEP>: <SEP> 128
<tb>: <SEP> - <SEP>: <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> - <SEP>: <SEP> 70 <SEP>: <SEP > 51
<tb> (*) not measurable
TABLE III
10% AND 14% CONSOLIDATION GROSS
REACTIVITY, SYNERESE AND RESISTANCE TO COMPRESSION

<tb>: <SEP> Grout <SEP> to <SEP> 10 <SEP>% <SEP> SiO2 <SEP>: <SEP> Grout <SEP> to <SEP> 14 <SEP>% <SEP> SiO2
<tb>: <SEP>: <SEP> Reactivity <SEP>: <SEP> Syne-: <SEP> Rc <SEP>: <SEP> Reactivity <SEP>: <SEP> Syn- <SEP>: <SEP> rc
<tb> in <SEP> mn <SEP> reads <SEP>% <SEP> Re <SEP> in <SEP> mn <SEP> reads <SEP>% <SEP> Re
<tb> Reference <SEP> to <SEP> to <SEP> to <SEP> to <SEP> to <SEP> to <SEP> to <SEP> to
<tb> silicate <SEP> 24 <SEP> H <SEP> 3 <SEP> months <SEP> 15 <SEP> j. <SEP> 7d. <SEP> 24 <SEP> h <SEP> 3 <SEP> months <SEP> 15 <SEP> d. <SEP> 7 <SEP> j.
<Tb>

silicate <SEP> 130 <SEP> 134 <SEP> 32.0 <SEP> 45 # 25 <SEP> 115 <SEP><SEP> 130 <SEP> 46.5 <SEP>;<SEP> 155 # 32
<tb>: <SEP> 1 <SEP>: 104 <SEP>: <SEP> 116 <SEP>: <SEP> 24.5 <SEP> 4.7 # 0.6 <SEP> 102 <SEP><SEP>:<SEP> 110 <SEP>: <SEP> 52.5 <SEP> 11.9 # 1.6 <SEP>
<tb>: <SEP> 2 <SEP>: 130 <SEP>: <SEQ> 117 <SEP>: <SEP> 35.0 <SEP>: <SEP> - <SEP>: <SEP> 98 <SEP> : <SEP> 121 <SEP>: <SEP> 53.5 <SEP>: <SEP>
<tb>: <SEP> 1 <SEP>: 130 <SEP>: <SEQ> 117 <SEP>: <SEP> 47.0 <SEP>: <SEP> - <SEP>: <SEP> 98 <SEP> : <SEP> 122 <SEP>: <SEP> 52.5
<tb>: <SEP> 2 <SEP>: <SEP> 91 <SEP>: <SEP> 101 <SEP>: <SEP> 11.0 <SEP> 4.5 # 0.6 <SEP><SEP> 82 <SEP>: <SEP> 99 <SEP>: <SEP> 25.5 <SEP> 11.8 # 1.7 <SEP>
<tb>: <SEP> 3 <SEP>: 122 <SEP>: <SEP> 102 <SEP>: <SEP> 31.5 <SEP>: <SEP> - <SEP>: <SEP> 96 <SEP> : <SEP> 99 <SEP>: <SEP> 31.5 <SEP>: <SEP><SEP>
<tb>: <SEP> 1 <SEP>: 107 <SEP>: <SEP> 101 <SEP>: <SEP> 37.0 <SEP>: <SEP> - <SEP>: 102 <SEP>: <SEP > 98 <SEP>: <SEP> 37.0 <SEP>: <SEP><SEP>
<tb>: <SEP> 1 <SEP>: <SEP> 65 <SEP>: <SEP> 57 <SEP>: <SEP> 12.0 <SEP> 6.2 # 0.5, <SE> 49 <SEP><SEP>:<SEP> 51 <SEP>: <SEP> 21.5 <SEP>, 11.9 # 2.2 <SEP>
<tb>: <SEP> 4 <SEP> 72 <SEP> 58 <SEP>: <SEP> 10.0 <SEP>: <SEP> - <SEP>: <SEP> 52 <SEP>: <SEP> 50 <SEP>: <SEP> 21.5 <SEP>: <SEP><SEP>
<tb>: <SEP> 2 <SEP>: <SEP> 70 <SEP>: <SEP> 58 <SEP>: <SEP> 9.5 <SEP>: <SEP> - <SEP>: <SEP> 59 <SEP>: <SEP> 51 <SEP>: <SEP> 21.5 <SEP>: <SEP>
<tb>: <SEP>: 112 <SEP>: <SEP> 102 <SEP>: <SEP> 5.5 <SEP> 6.0 # 1.2 <SEP><SEP> 80 <SEP>: <SEP > 79 <SEP>: <SEP> 21.5 <SEP> 13.0 # 2.1 <SEP>
<tb>: <SEP> 2 <SEP>: <SEP> 87 <SEP>: <SEP> 85 <SEP>: <SEP> 4.5 <SEP> 8.4 # 0.6 <SEP><SEP> 60 <SEP>: <SEP> 61 <SEP>: <SEP> 16 <SEP> 15.2 # 1.2 <SEP>
<tb>: <SEP> 5 <SEP>: 100 <SEP>: <SEP> 78 <SEP>: <SEP> 1.0 <SEP>: 7.7 + 1.0: <SEP> 65 <SEP> : <SEP> 64 <SEP>: <SEP> 16 <SEP> 15.2 # 1.0 <SEP>
<tb>: <SEP> 3 <SEP>: <SEP> 89 <SEP>: <SEP> 71 <SEP>: <SEP> 4.0 <SEP> 7.0 # 0.9 <SEP><SEP> 65 <SEP>: <SEP> 62 <SEP>: <SEP> 15.5 <SEP> 12.3 # 2.4 <SEP>
<tb>: <SEP> 1 <SEP>: <SEP> 60 <SEP>: <SEP> 51 <SEP>: <SEP> 4.0 <SEP>: 7.4 + 0.5: <SEP> 20 <SEP>: <SEP> 21 <SEP>: <SEP> 10.5 <SEP> 13.0 # 3.4 <SEP>
<tb>: <SEP> 6 <SEP>: <SEP> 58 <SEP>: <SEP> 51 <SEP>: <SEP> 4.0 <SEP>: <SEP> - <SEP>: <SEP> 22 <SEP>: <SEP> 22 <SEP>: <SEP> 10.5 <SEP>: <SEP>
<tb>: <SEP> 4 <SEP>: <SEP> 61 <SEP>: <SEP> 55 <SEP>: <SEP> 4.0 <SEP>: <SEP> - <SEP>: <SEP> 24 <SEP>: <SEP> 23 <SEP>: <SEP> 10.5 <SEP>: <SEP>
<tb> 89 <SEP> 78 <SEP> 2.7 <SEP> 7.6 <0.8 <SEP><SEP> 59 <SEP> 55 <SEP> 10.5 <SEP> 15.1 # 1, 8
<Tb>
Rc = Resistance to compression on test pieces (40 h80 min)
injected Fontainebleau sand, expressed in 105 Pa (bar).

 3rd series of examples - Influence of dilution.

Increase of the ratio by addition of acids (H3PO4, H2SO4,
HCl). Influence of the dilution. Passage Rm 3,6 to Rm 4,5.

We start with a SILICATE of Na COMMERCIAL of Rp = 3.3 which we want to transform into Rp = 4.4 by addition of acid. The starting Na silicate is diluted in such a way that
Final SiO2 = about 10 Z
Formulas (in grams)

<tb><SEP> 1 <SEP> 2 <SEP> 3
<tb> Silicate <SEP> Na <SEP> 3.31 <SEP> 385.5 <SEP> 385.5 <SEP> 385.5
<tb> Water <SEP> permuted <SEP>><SEP> 500 <SEP> 500 <SEP> 500
<tb> Water <SEP> permuted <SEP> nX <SEP> 1 <SEP> 113.3 <SEP> 101 <SEP> 110
<tb><SEP> 111
<tb> H3P04 <SEP> to <SEP> 85 <SEP> X <SEP> I1 <SEP> 7.97 <SEP>
<tb> H2S04 <SEP> to <SEP> 98 <SEP> Z <SEP> - <SEP> - <SEP> 10.7
<tb> H <SEP> C1 <SEP> to <SEP> 38 <SEP> Z <SEP> - <SEP> 19.9
<tb><SEP> 1006.77 <SEP> 1006.4 <SEP> 1006.2
<Tb>
Operative mode
The silicate is diluted with 500 g of water. The mixture (acid + remaining water) is poured into the diluted silicate. Ambient temperature between 20 and 250C.

Results formula 1 - obtaining a homogeneous liquid (easier preparation
than when starting from a commercial liquid silicate
undiluted).

formula 2 - the liquid obtained does not contain lumps at the moment,
but gelation after 3 days at the most storage.

formula 3 - the liquid obtained does not contain lumps immediately
after mixing, but gelling after 3 days at the most
storage.

Gelation by hot concentration
If within one hour after mixing, a sample of each of the preceding liquids is boiled, so as to cause a flow of water corresponding to about 50% of the total weight so as to have an SiO 2 of about 20%. %, we observe the following phenomena H3PO4 treatment: obtaining a more viscous liquid treatment H C1 and H2SO4: the concentration by boiling leads
gelation.

Conclusion
The liquid Na-silicate Rp = 4.4, ex H3PO4 is cold and hot stable. Ex-H C1 and H2SO4 products are not.

Ratio Increase - Passage Rm 2.7 (or 3.6) to Rm 3.9
The starting SALES SILICATES have the following characteristics:
SiO2 = 25.6% 30.8%
Na2O = 7.35 Z 11.8%
Rp = 3.48 2.61
Rm = 3.59 2.69
Formula in grams
4 5 6 7
Silicate Na 3.3 4450 4450 -
Silicate Na 2.6 - 3763 3763
H3PO4 at 85% 42.5 - 162.5
H2SO4 at 98% - 55.3 - 211.4
Permitted water 543.5 495 1302.5 1115.6
5036.0 5000.3 5228.0 5090.0
Operating mode
The mixture (acid + water) is poured with stirring into the commercial silicate. The ambient temperature is 200C.

Results formula 4: (3.3 + H 3 PO 4): the liquid obtained is homogeneous. Its pH = 11.23
Forecast obtained
SiO2 22.4 Z
Na2O 5.9%
Rp 3.90 3.79
Rm 4.20 3.91 Formula 5: (3.3 + H2SO4): After addition of the diluted sulfuric acid in 15 min. approximately, a viscous final silicate of pH = 11.07 is obtained
Forecast obtained
SiO2 22.75 Z
Na2O 5.96 Z
Rp 3.90 3.82
Rm 4.02 3.94 Formula 6: (2.6 + H3P04): the final liquid is homogeneous. Its pH = 11.26
Prevision obtained
SiO2 21.6%
Na2O 6.0%
Rp 3.90 3.60
Rm 4.02 3.71 Formula 7: (2.6 + H2SO4): the addition of the diluted sulfuric acid takes place in about 12 minutes, the final silicate (pH = 11.1) contains many lumps. After approximately 24 hours of storage. Separation in two distinct phases
one (A) upper liquid
the other (B) lower extremely viscous
Forecast obtained
(A) (B)
S102 21.3% 25.8%
Na2O 5.94% 6.5%
Rp 3.90 3.58 3.97
Rm 4.02 3.70 4.09
conclusions
At room temperature it is possible to pass from 3.3 to 3.9 using H3PO4 or H2SO4.

 On the other hand, when one starts from the 2.6 ratio and one tries to reach 3.9, the transformation is done normally only with H3PO4.

 The use of H2SO4 leads to the formation of two phases a liquid Rm = 3.7 + an extremely viscous Rm = 4! 1) in the latter case.

4th series of examples
LIQUID POTASSIUM SILICATE
Increasing ratio by addition of acids (H3PO4,
H2S04, H C1). Passage Rm 3.7 to Rm 4.5
We start from a K COMMERCIAL SILICATE characterized by
SiO2 = 21.5% ie Rp = 2.37
K20 = 9.07% Rm = 3.71
d = 1.271 which is treated with H3PO4, H2SO4 or H C1 to increase the ratio.

Formulas (in grams) 1 2 3 4
Silicate K 2.3 400 400 400 400
85% H3PO4 5.32 5.32
H2S04 at 98% - - 6.8
HCl at 38% - - - 15
Permitted water 95 45 93 -85
500.32 450.32 499.8 500
Operating mode
The mixture (acid + water) is poured into the K silicate with stirring at room temperature (20-250 ° C.).

Results formula 1: (3.7 + H3PO4 plus dliué): the liquid obtained is homogeneous.

Forecast obtained
SiO2 16.9
K20 5.8
Rp 2.90 2.91
Rm 4.54 4.56 Formula 2: (3.7 + H3PO4 less diluted): formation of lumps. After 30 minutes. about, separation into two layers.

formula 3: (3.7 + H2SO4): formation of lumps. After 30 min.

about two-layer separation, the lower being the more viscous.

Forecast obtained (liquid phase)
SiO2 16.0
KO 5.55
Rp 2.70 2.91
Rm 4.23 4.54 Formula 4: (3.7 + HCl): Immediate precipitation.

 These examples clearly illustrate that it is possible to obtain, under certain conditions, an increase in the SiO 2 / Me 2 O ratio by the use of a strong acid. This can be of appreciable interest if one starts from a silicate solution obtained by sodium attack.

 But we notice especially the particular behavior of phosphoric acid. In fact, samples of sodium and potassium silicates were analyzed, and the dissociated Na + and K + fraction was measured using selective Na + electrodes according to PL BAILEY-HEYDEN and Son Ltd 1976 .

 The results are summarized in the tables below.

SODIUM SILICATE

<tb> Sample <SEP>: <SEP> d <SEP>: <SEP> pH <SEP>: <SEP> Na20 <SEP>: <SEP> SiO2 <SEP>: <SEP> Rm <SEP>: <SEP > Na3PO4: <SEP> Na2SO4:
<tb>% <SEP> p / p <SEP>% <SEP> p / p <SEP>% <SEP> p / p <SEP>% <SEP> p / p
<tb> Silicate <SEP> 1.48 <SEP> 11.8 <SEP>: <SEP> 30.8 <SEP>: <SEP> 2.7
<tb>: <SEP> of <SEP> Na <SEP> 2,6 <SEP>
<tb>: <SEP> Silicate <SEP>: <SEP> 1.33 <SEP> 7.35 <SEP> 25.6 <SEP>: <SEP> 3.6 <SEP>
<tb>: <SEP> of <SEP> Na <SEP> 3.3 <SEP><SEP>:<SEP>.<September>
<Tb>

: <SEP> 4 <SEP>: <SEP> 1.24 <SEP>: <SEP> 11.2 <SEP>: <SEP> 5.9 <SEP>: <SEP> 22.4 <SEP>: <SEP> 3.9 <SEP>: <SEP> 1.14
<tb>: <SEP> 5 <SEP>: <SEP> 1.21 <SEP>: <SEP> 11.1 <SEP>: <SEP> 5.96: <SEP> 22.75: <SEP> 3 , 9 <SEP>: <SEP>: <SEP> 1.75
<tb>: <SEP> 6 <SEP>: <SEP> 1.28 <SEP>: <SEP> 11.3 <SEP>: <SEP> 6.0 <SEP>: <SEP> 21.6 <SEP >: <SEP> 3.7 <SEP>: <SEP> 4.26
<tb>: <SEP> 7 <SEP> (A) <SEP>: <SEP> 1.24 <SEP>: <SEP> 11.1 <SEP>: <SEP> 5.94: <SEP> 21, 3 <SEP>: <SEP> 3.7 <SEP>: <SEP>: <SEP> 5.9
<tb> (B) <SEP> 6.5 <SEP> 25.8 <SEP> 3.97 <SEP> = <SEP> Rp
<tb>: <SEP>: <SEP> 4.1 <SEP> = <SEP> Rm: <SEP>
<tb> (A) Analysis of the solution (B) Analysis of the viscous phase: it is a sodium silicate of
even slightly different Rm slightly more concentrated than the phase
corresponding aqueous solution.

POTASSIUM SILICATE

<tb> K2O <SEP> SiO2 <SEP> Rm <SEP> K3PO4 <SEP> K2SO4
<tb>: Silicate <SEP> of <SEP> K <SEP> 2.37 <SEP>: <SEP> 1.27 <SEP>: <SEP> 9.07 <SEP>: <SEP> 21.5 <SEP>:<SEP> 3,7 <SEP>: <SEP>:
<tb>: <SEP> 1 <SEP>: <SEP> 1.16 <SEP>: <SEP> 5.8 <SEP>: <SEP> 16.9 <SEP>: <SEP> 4.6 <SEP >: <SEP> 1.95 <SEP>:
<tb>: <SEP> 3 <SEP> (A) <SEP>: <SEP> 1.12 <SEP>: <SEP> 5.55 <SEP>: <SEP> 16.0 <SEP>: <SEP > 4.5 <SEP>: <SEP>: <SEP> 2.90
<tb> (A) Analysis of the solution.

Results
Note: To facilitate measurement, silicates are diluted
factor 2 with distilled water.

SODIUM SILICATE

<tb> Sample <SEP> + <SEP> Na + <SEP>%
<tb><SEP> Na <SEP> total <SEP> Na +
<tb> (diluted <SEP> 2) <SEP>;<SEP> Nat
<tb><SEP> Bm <SEP> 2.6 <SEP>: <SEP> 2.7 <SEP> ion <SEP>: <SEP> 0.54 <SEP> ion: <SEP> 20 <SEP>% <SEP>: <SEP> 3.9 <SEP> M / l
<tb><SEP> g / 1 <SEP> g / 1
<tb>: <SEP> Rm <SEP> 3.3 <SEP>: <SEP> 1.6 <SEP>: <SEP> 0.37 <SEP>: <SEP> 25 <SEP>% <SEP>: <SEP> 2.7
<tb> 1 <SEP> 1.29 <SEP> 0.34 <SEP> 26% <SEP> 2.3
<tb> 2 <SEP> 1.29 <SEP> 0.36 <SEP> 28% <SEP> 1.3
<tb>: <SEP> 3 <SEP>: <SEP> 1.64 <SEP>: <SEP> 0.41 <SEP>: <SEP> 25 <SEP>% <SEP>: <SEP> 2,3
<tb> 4 <SEP> 1.61 <SEP> 0.52 <SEP> 32% <SEP> 2.3
<tb>: <SEP> Comparison <SEP> with <SEP>: <SEP>
<tb>: <SEP> a <SEP> silicate <SEP> of <SEP>: <SEP> 1,25 <SEP>: <SEP> 0,30 <SEP>: <SEP> 24 <SEP>% <SEP >: <SEP> 2.1
<tb>: <SEP> Rm <SEP> 3.5 <SEP>. <SEP>. <SEP>.
<Tb>

POTASSIUM SILICATE

<SEP> K <SEP> K +
<tb><SEP> Sample <SEP> total <SEP> K + / Kt <SEP>% <SEP> SiO2
<tb><SEP> (diluted <SEP> 2) <SEP> Kt
<tb> Rm <SEP> = <SEP> 2.37 <SEP>: <SEP> 1.18 <SEP> ion <SEP>: <SEP> 0.21 <SEP> ion <SEP>: <SEP> 18 <SEP> 10 <SEP>: <SEP> 2.2 <SEP> M / l
<tb><SEP> g / 1 <SEP> g / 1
<tb> 1 <SEP> 0.87 <SEP> 16 <SEP> 19% <SEP> 1.63
<tb> 2
<tb> 0.85 <SEP> 0.20 <SEP> 23% <SEP> 1.5
<tb> solution
<Tb>
There is a slight difference in the percentage of cation between the two sulfuric and phosphoric acids, which is close to the analytical error. There is no satisfactory explanation for this difference in behavior.

Claims (5)

R E V E N D I C A T IO N S  1) New stable solution of high alkali metal silicates S102 / Me20, characterized in that it is obtained by treating an alkali silicate solution with a strong mineral acid.  2) New solution according to claim 1, characterized in that the strong mineral acid is constituted by phosphoric acid.  3) New solution according to one of claims 1 and 2, characterized in that the alkali metal is constituted by sodium and has an SiO 2 / Na 2 O molar ratio of at least 3.3 and advantageously at least equal at 3.9.  4) New composition for the consolidation of soils characterized in that it comprises a solution according to one of claims 1 to 3.  5) New composition according to claim 4, characterized in that it contains from 3 to 30% SiO 2 and more particularly from 10 to 20% SiO 2.