GB2041038A - Silicate compositions for soil stabilisation and foundry sand moulding - Google Patents

Abstract

A gelling composition useful for soil stabilisation and foundry sand moulding comprises water; an alkali metal silicate; an ester, particularly an alkyl alkanoate or one or more diesters of a C2 to C10 dibasic alkanoic acid; and rosin, a rosin ester, a rosin salt, a rosin acid or a rosin acid ester.

Description

SPECIFICATION Silicate compositions The present invention relates to an alkali metal silicate solution which is capable of forming a silica gel and to the use of such a solution in the stabilisation of the ground and similar applications.

Alkali metal silicate solutions may be converted to silica gels by the addition of a number of agents such as amides, acids, alcohols and esters. This property is put to good use in the stabilisation of unstable ground for building purposes by injecting into the ground a mixture of silicate solution and gelling agent which gels through the silicic acid to form a rigid silica gel. For this use esters are particularly valuable gelling agents because the gelling only takes place when the ester hydrolyses so there is an initial delay while hydrolysis takes place and this delay enables the silicate solution containing the gelling agent to be injected into the ground before gelling and subsequent hardening commences.

Among the esters which are commonly employed gelling agents for silicate solutions are included alkyl alkanoates particularly esters of Cl to C6 monobasic alkanoic acids with C1 and C5 alkano!s e.g. ethyl acetate, isopropylacetate and methyl propionate and the esters of dibasic alkanoic acids e.g.

esters of oxalic, succinic, glutaric and adipic acids. These dibasic acid esters have a number of advantages as gelling agents e.g. their rates of hydrolysis are such as to provide the right gelling time for the silicate solutions under the commonly encountered ambient temperature conditions at which such solutions are used. We have found however that there is a tendency for esters, particularly dibasic acid esters to be only sparingly miscible with aqueous alkali metal silicate solutions so that phase separation may occur resulting in the injection of an inhomogeneous mixture into the ground which does not gel uniformly. We have however devised a composition which overcomes this difficulty and which we have found in addition to have superior gelling properties.

According to the invention a gelling composition comprises water, an alkali metal silicate, an ester and rosin or a rosin ester or salt or a rosin acid or a rosin acid ester or salt.

Preferably, the ester comprises one or more diesters of a C2 to C,O dibasic alkanoic acid.

The C2 to C,O dibasic alkanoic acids are oxalic, masonic, succinic, glutaric, adipic, pimelic, suberic, azelaic and sebacic acids and of these succinic, glutaric and adipic acids are preferred particularly as a mixture of two from the three e.g. glutaric and adipic acids, or all three together. The diester is preferably a diester of a C, to C5 alkanol particularly the dimethyl or diethyl ester or mixed methyl/ethyl ester.

Rosin is a naturally occurring product comprising predominantly a mixture of so-called rosin or resin acids and although for economic reasons it is preferred to use rosin itself or a rosin ester or salt one or more of the rosin acids or rosin acid esters or salts may be used i.e. an abietic type acid e.g.

abietic, levopimaric, neoabietic or palustric acids, a pimaric type acid e.g. pimaric or an isopimaric acid, or elliotinoic acid or sandaracopimaric acid. The esters may suitably be esters of C, to C6 alkanols e.g. a methyl or ethyl ester and the salts alkali metal e.g. sodium, alkaline earth metal e.g. calcium or other metal e.g. zinc or aluminium or amine salt. The rosin or rosin acid may also be modified by commercially known processes which are used to improve its properties. In particular the rosin or rosin acid may have been partially or completely hydrogenated or partially dehydrogenated, processes which are employed to increase the colour stability of the product.

The alkali metal silicate may be a sodium potassium or lithium silicate or polysilicate more usually a sodium salt for economic reasons. The molar ratio of SiO2 :M20 where M is the alkali metal is preferably between 2.0 and 5.0. The relative amounts of the ingredients of the composition may vary widely but the preferred ranges are 10 to 50 wt % alkali metal silicate (as solid), 1 to 1 5 wt % ester, 0.01 to 10 wt % preferably 0.02 to 5 wt % of the rosin, rosin ester or salt, rosin acid or rosin acid ester or salt and the balance water.

Although the compositions according to the invention may be used in the stabilisation of the ground as described earlier in this specification this is by no means their only application and they may find use in other fields e.g. in foundry sand moulding compositions and in water-sealing fissures or voids in rock and sealing a surface where water impermeability rather than significant mechanical strength is required. In this latter application a more dilute silicate solution which sets to a "soft" gel may be used.

The compositions according to the invention maintain a substantially phase stable liquid system for a sufficiently long time to enable the silicate solution to reach its point of application, although it will be appreciated that once the ingredients have been blended the composition must be used as soon as possible otherwise significant gelling will take place before the solution is in the region where the stabilisation is required. In practice it is easier first to dissolve the rosin, rosin ester or salt, rosin acid or rosin acid ester or salt in the ester rather than to add it directly to the silicate solution because by so doing the additive is more rapidly dispersed in the silicate solution.

The invention will now be further illustrated by reference to the following Examples.

EXAMPLES 1-18 A solution was made up consisting of 60 mls of a sodium silicate solution (containing 39.3% solids SiO2: Na20 molar ratio 3 :3), 30 mls water and 10 mls of a gelling agent mixture which consisted in turn of 0.2 wt % dimethylsuccinate, 75.7 wt % dimethylglutarate and 24.1 wt % dimethyladipate.

Varying amounts of rosin, methylrosinate or ethyirosinate were added to samples of the solution and each sample tested by charging to a stoppered 100 ml measuring cylinder and inverting the cylinder 70 times over a period of 30 seconds. The volumes of gelling agent (diesters) which had separated from the solution was noted every five minutes starting from the first inversion of the cylinder.

For comparative purposes a number of other tests were carried out as shown in the following Table as Examples 7 to 1 8. In these tests a wide range of emulsifying agents were evaluated which might have been expected to improve the miscibility of the diester gelling agent with the silicate solution.

It can be seen from the Table that there is less separation af the dimethylesters when rosin or a rosin ester is present than in the absence of such an additive or in the presence of a standard emulsifying agent. In addition, the solution containing the rosin or rosin ester starts to gel sooner than the comparative solutions and the gelling is consistent throughout the solution rather than taking place in a localised manner at one or more points.In practice consistent gelling throughout the silicate solution is important when it is realised that mixing after injection into the ground is usually impossible. %of gelling agent separated in time (mins) Example Additive Concentration 5 10 15 20 25 30 35 40 1 - - 20 50 70 80 82 85 88 local gelling 2 Rosin 1% wt/vol 0 10 20 20 35 gelling throughout 3 Ethyl rosinate soln.* 1% vol/vol 0 10 20 20 45 ,, 4 Ethyl rosinate soln.* 2% ,, ,, 0 10 15 25 30 ,, ,, 5 Ethyl rosinate soln.* 3% ,, ,, 0 0 10 15 20 ,, ,, 6 Methyl rosinate soln.* 3% ,, ,, 0 0 10 15 20 ,, ,, 7 Noyl pohenol ethoxylate 1% ,, ,, 10 30 45 50 62 68 75 local gelling 8 C13-C15. alkanol ethoxylate 1% ,, ,, 10 30 45 55 65 70 80 9 Polypropylene glycol monomethyl ether 1% ,, ,, 15 55 75 82 85 88 90 ,, ,, 10 Ethoxylated polypropylene glycol 1% ,, ,, 4 20 45 60 70 75 80 ,, ,, 11 Silicone ethoxylate 1% ,, ,, 10 28 43 50 65 70 75 ,, ,, 12 Ethoxylated phenol/ 1% ,, ,, 12 30 45 55 65 70 75 ,, ,, formaldehyde resin 13 Triethanolamine poleate 1% ,, ,, 20 35 50 65 75 80 85 ,, ,, 14 Coco diethanolamide 1% ,, ,, 15 30 45 65 75 80 85 ,, ,, 15 Dimethyl C13-C15 alkylamine 1% ,, ,, 25 40 55 70 78 83 88 ,, ,, 16 Linear C13 alkyl sulphate 1% ,, ,, 30 60 70 75 78 80 83 ,, ,, 17 Dodecylbenzene sulphonate 1% ,, ,, 28 50 63 70 75 80 85 ,, ,, 18 Sodium dodecyl benzene sulphonate 1% ,, ,, 30 55 65 73 78 82 85 ,, ,, *The additives referred to as ethyl and methyl rosinates were prepared by refluxing for three hours 25 grams rosin with 80 mls ethanol or methanol respectively and 1 gram of para-toluene sulphonic acid as esterification catalyst. The resulting solution of the ester was used in the experiments without refinement.

EXAMPLES 19 and 20 In the following Examples the silicate solution which was used comprised 36% wt/wt solids with a SiO2:Na2O weight ratio of 2.9:1. The hardener comprised a mixture of diesters of the following composition: dimethylsuccinate 5% by weight dimethylglutarate 72% by weight dimethyladipate 23% by weight and was used in 10% by volume concentration.

Four experiments (Examples 1 9 and 20) were carried out to determine the effect of rosin on the compressive strength of a grout made with the silicate solution. The base material was Chelford 50 sand which was used wet and into 5 parts of which was injected 1 part of the silicate solution to produce cylindrical samples 5 cm long with 5 cm diameter. After standing for 48 hours the unconfined compressive strength of the sample was measured on a tensometer. The results were as follows:

Unconfined compressive strength Kg/cm2 Concentration of silicate solution 1% wt/wt rosin based on Example in the grouting mixture % by vol the hardener I No rosin 19 I= 60 28 13 20 70 37 24

Claims (15)

1. A gelling composition which comprises water, an alkali metal silicate, an ester and rosin, d rosin ester or salt, or a rosin acid or a rosin acid ester or salt.

2. A gelling composition according to Claim 1 in which the ester comprises an ester of a C1 to C6 monobasic alkanoic acid with a C, to C5 alkanol.

3. A gelling composition according to Claim 2 in which the ester is ethyl acetate, isopropylacetate or methylpropionate.

4. A gelling composition according to Claim 1 in which the ester comprises one or more diesters of a C2 to CIO dibasic alkanoic acid.

5. A gelling composition according to Claim 4 in which the diester comprises a diester of succinic, adipic or glutaric acid or a mixture of diesters of two of these three or of all of these three acids.

6. A gelling composition according to Claim 4 or Claim 5 in which the diester is a diester of a C1 to C5 alkanol.

7. A gelling composition according to Claim 6 in which the diester is a diester of methanol, ethanol or a mixture of methanol and ethanol.

8. A gelling composition according to any one of the preceding claims in which the rosin ester or rosin acid ester is the ester of a C1 to C6 alkanol.

9. A gelling composition according to any one of Claims 1 to 7 in which the rosin salt or rosin acid salt is an alkali metal salt, an alkaline earth metal salt, a zinc salt, an aluminium salt or an amine salt.

10. A gelling composition according to any one of the preceding claims in which the rosin or rosin acid has been modified by partial or complete hydrogenation or by partial dehydrogenation.

11. A gelling composition according to any one of the preceding claims in which the alkali metal silicate is a sodium silicate or polysilicate.

12. A gelling composition according to any one of the preceding claims in which the molar ratio of Si02 : M2O in the alkali metal silicate is in the range 2.0 to 5.0 where M is the alkali metal.

13. A gelling composition according to any one of the preceding claims which contains 10 to 50 wt % alkali metal silicate (as solid), 1 to 1 5 wt % ester, 0.01 to 10 wt % rosin, rosin ester or salt, rosin acid or rosin acid ester or salt and the balance water.

14. A method of stabilising the ground or of sealing a surface or of forming a foundry sand mould which comprises contacting the ground, surface or sand with a composition according to any one of the preceding claims.

15. A mixture for use in forming the composition according to any one of Claims 1 to 13 which comprises a solution in an ester of rosin, rosin ester or salt or a rosin acid or a rosin acid ester or salt.

1 6. A gelling composition substantially as described in any one of Examples 1 to 6, 1 9 and 20.