[0001] This invention relates to detergent compositions stable to chlorine separation suitable
as machine dish washing detergents or industrial detergents, and to agents for producing
said compositions.
[0002] Machine dish washing detergent compositions for example consist mainly of
- alkali metal phosphate
- alkali metal silicate
- surfactant
- organic chlorine compound.
[0003] The alkali metal phosphate, usually sodium tripolyphosphate, primarily serves as
complexing agent for calcium and magnesium ions.
[0004] The alkali metal silicate normally is a sodium silicate having a molar ratio Si0
2:Na
2O of 3.50 to 0.75. Usually, use is made of so-called sodium metasilicate, which implies
that said ratio lies about 1. The purpose of the silicate is to provide a high pH,
which is needed int. al. for hydrolysis of edible fat rests, and to have a corrosion
preventing effect.
[0005] The sodium metasilicate may be either practically anhydrous or be present as a hydrate
with crystal bound water. The commercially most usual hydrate is the crystal form
called pentahydrate. This product is usually written as Si02. N
820 - 5H
20, but actually is a tetrahydrate of the salt Na
2H
2SiO
4. This crystal form is hereinafter called "pentahydrate".
[0006] The pentahydrate offers several advantages over the anhydrous sodium metasilicate
in machine dish washing detergent compositions, int. al. because it is more readily
soluble and considerably cheaper. The introduction of water into a machine dish washing
detergent composition in powder form, however, as experience has shown, entails problems
regarding the stability of the organic chlorine compounds. These readily hydrolyzed
compounds in fact give off chlorine gas in a moist environment, which amounts to a
considerable technical problem. For these reasons, use is preferably made of anhydrous
sodium metasilicate in said products.
[0007] The surfactant usually is a low-foaming non-ionic surfactant, preferably a block
polymer of ethylene and propylene oxide. Its task is to contribute to wetting and
emulsification simultaneously as it shall have an antifoaming effect on for example
proteins.
[0008] The organic chlorine compound or chlorine carrierfunctions as an oxidative bleaching
agent which has the task of attacking deposits of int. al. coffee, tea and fruit juices.
The economically most favourable chlorine carrier is trichloroisocyanuric acid, but
it is very instable and gives off chlorine too easily to permit being used in practice.
Salts of dichloroisocyanuric acid are therefore used in most cases and the sodium
salt has, primarily for economical reasons, been most widely utilized.
[0009] Apart from the above-mentioned main components, machine dish washing detergents often
also contain varying quantities of alkalimetal carbonates and bicarbonates, corrosion
inhibitors, dyes and perfume.
[0010] What has been said above about machine dish washing detergents is also true, in applicable
parts, to industrial detergent compositions generally.
[0011] There have been made great efforts to stabilize the organic chlorine compounds in
detergent compositions and thereby to reduce the problem of a premature chlorine gas
development. It has been tried, by addition of reducing agents (cf. German Patent
1,111,198) or by adjustment of pH with the aid of a combination of boron oxide and
soda (cf. French Patent 1,537,311) to reduce the tendency of chlorine separation in
alkali salts of dichloroisocyanuric acid. There is also described a method of adding
paraffin oil to compositions based on these chlorine compounds (cf. U.S. Patent 3,390,092).
Trichloroisocyanuric acid also has been stabilized for instance by means of an olefin
having a carbon-carbon double bond, one carbon atom of said double bond being tertiary
(cf. British Patent 848,397). Common to all of these methods is that even though they
imply a certain improvement as to stability to chlorine separation, the result is
far from satisfactory. With the use of sodium metasilicate pentahydrate in detergents
an uncontrolled discharge of chlorine gas therefore still is a production-technical
problem for the industries producing the detergents and also an important practical
problem for the consumer because of chlorine smell and lower bleaching effects.
[0012] It has now been found that the tendency of chlorine separation in organic chlorine
compounds can be reduced and a surprisingly good result be reached by surface-treating
said chlorine compounds in granular form with a hydrophobic substance. However, a
prerequisite is that the chlorine compounds are present in granulated form, with a
particle size of about 0.5 to 5 mm. Pulverulent compounds cannot be surface-treated
in this way since caking of the product will result from such a treatment. Machine
dish washing detergents and industrial detergents based on surface-treated organic
chlorine compounds show a high degree of stability to chlorine separation. Surface-treated
trichloroisocyanuric acid also gives acceptable results when used in machine dish
washing detergents and industrial detergents.
[0013] A considerable reduction of the chlorine losses is obtained not only at the storing
of the finished machine dish washing detergent but also in the production thereof
when use is made of a chlorine compound surface-treated in accordance with the present
invention.
[0014] This invention thus relates to a detergent composition comprising alkali metal phosphate,
alkali metal silicate, a surfactant, a chlorinated triazine trione of formula (1)

wherein X is Cl, Na or K, or when X is Na, the dihydrate thereof, and optionally conventional
additives. Said composition is characterized in that the chlorinated triazine trione
of formula (I) is in the form of granules, said granules having a size of about 0.5
to 5 mm and being coated with a thin hydrophobic layer of a diester of phthalic acid
or adipic acid with an alcohol having 4-18 carbon atoms in an amount of 3-9% by weight,
calculated on the amount of chlorinated triazine trione of formula (I).
[0015] The invention further relates to an agent for producing the detergent composition,
said agent being characterized in that it consists of granules of chlorinated triazine
trione of formula (I)

wherein X is CL, Na or K, or the dihydrate of the triazine trione of formula (I) when
X is Na, said granules having a size of about 0.5 to 5 mm and being coated with a
thin hydrophobic layer of a diester of phthalic acid or adipic acid with an alcohol
having 4-18 carbon atoms in an amount of 3-9% by weight, calculated on the amount
of the chlorinated triazine trione of formula (I).
[0016] Different embodiments of the composition according to the invention comprise a machine
dish washing detergent composition and an industrial detergent composition, respectively.
[0017] The surface-treatment of the chlorinated triazine trione is preferably performed
such that the hydrophobic substance in liquid form or dissolved in a readily volatile
solvent is added by portions under some kind of agitation to the granulate chlorinated
triazine trione which is thereby coated with a thin film of hydrophobic material effectively
protecting the labile chlorine compound from contact with water.
[0018] The hydrophobic film-forming substances utilized in the surface-treatment are diesters
of certain carboxylic acids, particularly phthalic acid or adipic acid, which surprisingly
have proved to yield excellent results.
[0019] The diesters preferably utilized in the invention are diesters of phthalic acid or
adipic acid with an alcohol having 4-18 carbon atoms, preferably a straight or branched
alcohol having 6-12 carbon atoms. The following diesters have proved to be particularly
useful:
phthalate 610*
di-(2-ethyl hexyl)phthalate
diisodecyl phthalate
di-(2-ethyl hexyl)adipate
diisodecyl adipate
*phthalate 610 is the trade name of a fraction of diesters of phthalic acid and alcohols
having 6-10 carbon atoms.
[0020] The most important physical property required in the diesters utilized for the surface-treatment
is that they shall be sufficiently water-repellent in order that also a thin layer
of the diester shall provide a fully satisfactory moisture protection for the enclosed
chlorine compound. Further, it is advantageous if the diester is liquid at room temperature
or has a melting point not too far above said temperature, preferably below 70°C.
Use can also be made of diesters having a higher melting point, in which case these
are first dissolved in a volatile solvent whereupon the surface-treatment proper is
performed and the solvent is finally driven off by heating of the granulate surface-treated
product.
[0021] Naturally, it is also of great importance for the diesters to have a good adhesion
to the granulate chlorine compound.
[0022] The chlorinated triazine compounds of formula I comprise
Na-dichloroisocyanurate
Na-dichloroisocyanurate dihydrate
K-dichloroisocyanu rate
trichloroisocyanuric acid.
[0023] A complex between K-dichlorocyanurate and trichloroisocyanuric acid is also well
suited for use with the present invention.
[0024] The surface-treatment provides an effect already an astonishingly small amounts of
the hydrophobic substance. For most of the substances tested a content of 3-9% by
weight calculated on the chlorinated triazine trione has proved to be sufficient.
In most cases it has even been found disadvantageous to exceed that amount as this
results in the surface-treated product becoming sticky and having a tendency of aggregating.
[0025] A machine dish washing detergent composition being an embodiment of the present invention
has the following constitution as regards its essential components (the percentages
are percentages by weight):
- alkalimetal phosphate in an amount of 25-60%, preferably 40-50%,
- alkalimetal silicate in an amount of 30-70%, preferably 40-60%, molar ratio SiO2:Na2O(K2O) of 3.500.75, preferably about 1, and a water content of 0-60%, preferably 0-5%
or 35-45%,
- a low foaming non-ionic type surfactant in an amount of 0.5-3%, preferably 1-2%,
- a chlorinated triazine trione of formula (I), surface-treated with a hydrophobic
substance in an amount of 1-5%, preferably 1-3% (the amount of hydrophobic substance
is 3-9%, preferably 5-8%, calculated on the chlorinated triazine trione),
- conventional additives in an amount of 0-40%, preferably 0-20%.
[0026] An industrial detergent composition being another embodiment of the present invention
has the following constitution (the percentages are percentages by weight):
- alkalimetal phosphate in an amount of 25-60%, preferably 40-50%,
- alkalimetal silicate in an amount of 20-70%, preferably 25-45%, molar ratio SiO2:Na2O(K2) of 3.50-0.75, preferably about 1, and a water content of 0-60%, preferably 0-5%
or 3545%,
- alkalimetal hydroxide in an amount of 0-30%, preferably 10-20%,
- a low foaming non-ionic type surfactant in an amount of 0.5-3%, preferably 1-2%,
- a chlorinated triazine trione of formula (I), surface-treated with a hydrophobic
substance, in an amount of 1-10%, preferably 2-5% (the amount of hydrophobic substance
is 3-9%, preferably 5-8%, calculated on the chlorinated triazine trione),
- conventional additives in an amount of 0-40%, preferably 0-20%.
[0027] As will appear from Example 3 below, it is possible to produce with the aid of the
above-described surface-treating method a detergent composition based on sodium metasilicate
pentahydrate which is at least equally stable to chlorine separation as a corresponding
product based on anhydrous sodium metasilicate and a non-treated organic chlorine
compound. The amount stated of hydrophobic material for the surface treatment, usually
5-8% of the amount of organic chlorine compound, usually constitutes but 0.050.25%
of the total detergent composition. The additional cost of said raw product and of
the extra operation the surface treatment involves, is small compared with the savings
in raw material costs realized by turning from anhydrous metasilicate to the pentahydrate
thereof.
[0028] Especially astonishing is that very good results are also obtained with trichloroisocyanuric
acid (see Example 2).
[0029] Another advantage gained by the surface-treating method indicated thus resides in
the possibility of being able to replace the anhydrous metasilicate in detergents
with the corresponding pentahydrate, retaining the stability to chlorine separation
of the detergents. An alternative application of the surface-treating method is to
provide compositions based on anhydrous metasilicate and a surface-treated organic
chlorine compound, said compositions being extremely stable to chlorine separation.
However, such a formulation will be relatively expensive and may probably be used
only for special purposes.
[0030] The following Examples are meant to illustrate the invention without restricting
it in any way.
Example 1
[0031] The effect of a surface-treatment of Na-dichloroisocyanurate for machine dish washing
detergents stored at 30°C/85% relative moisture was examined. The samples were stored
in boared cartons treated with polyethylene. The chlorine content was determined by
titration according to the iodine-thiosulphate method.
[0032] The following machine dish washing detergent composition was used in the tests:

[0033] A great many different substances were tested as surface-treating agents. The substances
most useful in practice are indicated in Table 1.
[0034] The surface-treating agent was added by portions under vigorous agitation to the
granulate chlorine compound. After finished addition the agitation was continued for
a further 2-3 minutes. Low viscous substances were added at room temperature whereas
high viscous substances as well as solid compounds were first heated to' suitable
viscosity. The surface treating agent was added in an amount of 7%, and in some cases
also 5%, calculated on the chlorine compound. A reference test was made, in which
the surface-treating agent was replaced by soda which is totally inert in this connection.
[0035] The chlorine content of the various dish washing detergent compositions which thus
differ only with regard to the surface-treatment of sodium dichloroisocyanurate, was
determined as a function of the storage time.
[0036] The results of the tests are given in Table 1.

Example 2
[0037] The effect of a surface-treatment of trichloroisocyanuric acid for machine dish washing
detergents stored at 30°/85% relative moisture was examined. The samples were stored
in board cartons treated with polyethylene. The chlorine content was determined by
titration according to the iodine-thiosulphate method.
[0038] The following machine dish washing detergent composition was used in the tests:

[0039] A great many different substances were tested as surface-treating agents. The substances
most useful in practice are indicated in Table 2.
[0040] The surface-treating agent was added by portions under vigorous agitation to the
granulate chlorine compound. After finished addition agitation was continued for a
further 2-3 minutes. Low viscous substances were hereby added at room temperature
whereas high viscous substances as well as solid compounds were first heated to a
suitable viscosity. The surface-treating agent was added in an amount of 6%, calculated
on the chlorine compound. A reference test was made in which the surface-treating
agent had been replaced by soda which is entirely inert in this connection.
[0041] The chlorine content of the different machine dish washing detergent compositions
which thus differ only with regard to the surface-treatment of trichloroisocyanuric
acid, was determined as a function of the storage time.
[0042] The results of the tests are indicated in Table 2.

Example 3
[0043] The effect of the surface-treatment of the organic chlorine compound for machine
dish washing detergents based on anhydrous metasilicate and the pentahydrate thereof,
respectively, was tested and compared with regard to stability to chlorine separation.
Use was made as surface-treating agent of di-(2-ethyl hexyl)phthalate in an amount
of 7% calculated on the organic chlorine compound. The following formulations were
used:

[0044] Reference tests were made for the two formulations (reference A and reference B,
respectively), in which the di-(2-ethyl hexyl)-phthalate was replaced by soda. The
procedure applied at the surface-treatment like the execution and evaluation of the
tests were analogous with those in Example 1.
[0045] The results of the examination will appear from Table 3. As is evident, the surface
treatment had a positive effect in both cases. It also appears from the Table that
a machine dish washing detergent based on metasilicate pentahydrate and surface-treated
chlorine compound (A) will be at least equally stable to chlorine separation as a
detergent based on anhydrous metasilicate and untreated chlorine compound (B).

Example 4
[0046] The effect of a surface-treatment of sodium dichloroisocyanurate for detergents stored
at 30°C/85% relative moisture was examined. The samples are stored in board cartons
treated with polyethylene. The chlorine content was determined by titration according
to the iodine-thiosulphate method.
[0047] The following detergent composition was used in the tests:

[0048] A great many different substances were tested as surface-treating agents. The substances
most useful in practice are indicated in Table 2.
[0049] The surface-treating agent was added by portions under vigorous agitation to the
granulate chlorine compound. After finished addition agitation was continued for a
further 2-3 minutes. Low viscous substances were hereby added at room temperature
whereas high viscous substances as well as solid compounds were first heated to a
suitable viscosity. The surface treating agent was added in an amount of 7%, calculated
on the chlorine compound. A reference test was made, in which the surface treating
agent was replaced by soda which is entirely inert in this connection.
[0050] The chlorine content of the different detergent compositions which thus differed
only with regard to the surface-treatment of sodium dichloroisocyanurate, was determined
as a function of the storage time.
[0051] The results of the tests are indicated in Table 4.

Example 15
[0052] 18.6 kg of granulate sodium dichloroisocyanurate were charged into a Lodiger mixer
of 50 I. Under vigorous agitation 1.4 kg of di-(2-ethyl-hexyl)phthalate was added
through a fine nozzle. The time of supply amounted to 3-5 minutes. After finished
supply agitation was continued for a further few minutes, whereupon the mixer was
emptied.
1. A detergent composition comprising alkali metal phosphate, alkali metal silicate,
a surfactant, a chlorinated triazine trione of the formula

wherein X is Cl, Na or K, or when X is Na, the dihydrate thereof, and optionally conventional
additives, characterized in that the chorinated triazine trione of formula (I) has
the form of granules, said granules having a size of about 0.5 to 5 mm and being coated
with a thin hydrophobic layer of a diester of phthalic acid or adipic acid with an
alcohol having 4-18 carbon atoms in an amount of 3-9% by weight, calculated on the
amount of the chlorinated triazine trione of formula (I).
2. The composition of claim 1, characterized in that the alcohol is a straight or
branched alcohol having 6-12 carbon atoms.
3. The composition of claim 1, characterized in that the hydrophobic layer comprises
a fraction of diesters of phthalic acid and alcohols having 6-10 carbon atoms, di-(2-ethyl-hexyl)phthalate,
diisodecyl phthalate, di-(2-ethy)-hexyi)adipate and/or diisodecyl adipate.
4. A machine dish washing detergent composition according to one or more of claims
1-3, characterized in that it comprises
25-60% by weight of alkali metal phosphate
30-70% by weight of alkali metal silicate
0.5-3% by weight of surfactant
1-5% by weight of chlorinated triazine trione
3-9% by weight of diester, calculated on the amount of chlorinated triazine trione
0-40% by weight of conventional additives.
5. An industrial detergent composition according to one or more of claims 1-3, characterized
in that it comprises
25-60% by weight of alkali metal phosphate
20-70% by weight of alkali metal silicate
0-30% by weight of alkali metal hydroxide
0.5-3% by weight of surfactant
1-10% by weight of chlorinated triazine trione
3-9% by weight of diester, calculated on the amount of chlorinated triazine trione
0-40% by weight of conventional additives.
6. An agent for producing a detergent composition, characterized in that the agent
comprises granules of chlorinated triazine trione of the formula

wherein X is Cl, Na or K, or the dihydrate of the triazine trione of formula (1) when
X is Na, said granules having a size of about 0.5 to 5 mm and being coated with a
thin hydrophobic layer of a diester of phthalic acid or adipic acid with an alcohol
having 4-18 carbon atoms in an amount of 3-9% by weight, calculated on the amount
of the chlorinated triazine trione of formula (I).
7. The agent of claim 6, characterized in that the alcohol is a straight or branched
alcohol having 6-12 carbon atoms.
8. The agent of claim 6, characterized in that the hydrophobic layer comprises a fraction
of diesters of phthalic acid and alcohols having 6-10 carbon atoms, di-(2-ethyl hexyl)phthalate,
diisodecylphthalate, di-(2-ethyl hexyl)adipate and/or diisodecyladipate.
1. Reinigungsmittelzusammensetzung, umfassend Alkalimetallphosphat, Alkalimetallsilikat,
einen oberflächenaktiven Stoff, ein chloriertes Triazintrion der Formel

in der X=CI, Na oder K, oder, wenn X=Na, das Dihydrat davon, sowie falls erwünscht
herkömmliche Zusätze, dadurch gekennzeichnet, dass das chlorierte Triazintrion der
Formel (I) die Form von Körnchen aufweist, die eine Grösse von etwa 0,5-5 mm besitzen
und mit einer dünnen hydrophoben Schicht eines Diesters von Phthalsäure oder Adipinsäure
mit einem Alkohol mit4-18 Kohlenstoffatomen in einer Menge von 3-9 Gew.-%,-bezogen
auf die Menge des chlorierten Triazintrions der Formel (I), überzogen sind.
2. Zusammensetzung nach Anspruch 1, dadurch gekennzeichnet, dass der Alkohol ein geradkettiger
oder verzweigt kettiger Alkohol mit 6-12 Kohlenstoffatomen ist.
3. Zusammensetzung nach Anspruch 1, dadurch gekennzeichnet, dass die hydrophobe Schicht
eine Fraktion von Diestern von Phthalsäure und Alkoholen mit 6-10 Kohlenstoffatomen,
di-(2- Äthylhexyl)phthalat, Diisodecylphthalat, di-(2-Äthylhexyl)adipat und/oder Diisodecyladipat
umfasst.
4. Geschirrspülmaschinen-Reinigungsmittelzusammensetzung nach einem oder mehreren
der Ansprüche 1-3, dadurch gekennzeichnet, dass sie
25-60 Gew.-% Alkalimetallphosphat,
30-70 Gew.-% Alkalimetallsilikat,
0,5-3 Gew.-% eines oberflächenaktiven Stoffes,
1-5 Gew.-% chlorierten Triazintrions,
3-9 Gew.-% Diester, bezogen auf die Menge chlorierten Triazintrions,
0-40 Gew.-% herkömmlicher Zusätze umfasst.
5. Industrielle Reinigungsmittelzusammensetzung nach einem oder mehreren der Ansprüche
1-3, dadurch gekennzeichnet, dass sie
25-60 Gew.-% Alkalimetallphosphat,
20-70 Gew.-% Alkalimetallsilikat,
0-30 Gew.-% Alkalimetallhydroxyd,
0,5-3 Gew.-% eines oberflächenaktiven Stoffes,
1-10 Gew.-% chlorierten Triazintrions,
3-9 Gew.-% Diester, berechnet auf die Menge des chlorierten Triazintrions,
0-40 Gew.-% herkömmlicher Zusätze enthält.
6. Mittel zur Herstellung einer Reinigungsmittelzusammensetzung, dadurch gekennzeichnet,
dass das Mittel Körnchen von chloriertem Triazintrion der Formel

umfasst, wo X=CI, Na oder K, oder das Dihydrat des Triazintrions der Formel (1), wenn
X=Na, wobei die genannten Körnchen eine Grösse von etwa 0,5-5 mm aufweisen und mit
einer dünnen hydrophoben Schicht eines Diesters von Phthalsäure oder Adipinsäure mit
einem Alkohol mit 4-18 Kohlenstoffatomen in einer Menge von 3-9 Gew.-%, bezogen auf
die Menge des chlorierten Triazontrions der Formel (1), überzogen sind.
7. Mittel nach Anspruch 6, dadurch gekennzeichnet, dass der Alkohol ein geradkettiger
oder verzweigt kettiger Alkohol mit 6-12 Kohlenstoffatomen ist.
8. Mittel nach Anspruch 6, dadurch gekennzeichnet, dass die hydrophobe Schicht eine
Fraktion von Diestern von Phthalsäure und Alkoholen mit 6-10 Kohlenstoffatomen, di-(2-Äthylhexyl)phthalat,
Diisodecylphthalat, di-(2-Äthylhexyl)adipat und/oder Diisodecyladipat umfasst.
1. Composition détergente comprenant un phosphate de métal alcalin, un silicate de
métal alcalin, un surfactif, une triazine trione chlorée de formule:

(dans laquelle X représente CI, Na ou K), ou bien, quand X représente Na, son dihydrate
et éventuellement des additifs classiques, composition caractérisée en ce que la triazine
trione chlorée de formule (I) a la forme de granules ayant une dimension d'environ
0,5 à 5 mm et qui sont revêtus d'une mince couche hydrophobe d'un diester de l'acide
phtalique ou de l'acide adipique avec un alcool ayant 4-18 atomes de carbone, en une
quantité de 3-9% en poids, par rapport à la quantité de la triazine trione chlorée
de formule (1).
2. Composition selon la revendication 1, caractérisée en ce que l'alcool est un alcool
linéaire ou ramifié ayant 612 atomes de carbone.
3. Composition selon la revendication 1, caractérisée en ce que la couche hydrophobe
comprend une fraction de diesters de l'acide phtalique et d'alcools ayant 610 atomes
de carbone, le phtalate de bis(2-éthylhexyle), le phtalate de diisodécyle, l'adipate
de bis(2-éthylhexyle) et/ou l'adipate de diisodécyle.
4. Composition détergente pour lavage de la vaisselle en machine selon une ou plusieurs
des revendications 1 à 3, composition caractérisé en ce qu'elle comprend:
25-60% en poids de phosphate de métal alcalin,
30-70% en poids de silicate de métal alcalin,
0,5-3% en poids d'un surfactif,
1-5% en poids de triazine trione chlorée,
3-9% en poids de diester, proportion calculée par rapport à la quantité de triazine
trione chlorée,
0-40% en poids d'additifs classiques.
5. Composition de détergents industriels selon une ou plusieurs des revendications
1 à 3, caractérisée en ce qu'elle comprend:
25―60% en poids de phosphate de métal alcalin,
20-70% en poids de silicate de métal alcalin,
0-30% en poids d'hydroxyde de métal alcalin,
0,5-3% en poids de surfactif,
1-10% en poids de triazine trione chlorée,
3-9% en poids d'un diester, quantité calculée par rapport à la quantité de la triazine
trione chlorée,
0-40% en poids d'additifs classiques.
6. Agent pour produire une composition détergente, caractérisé en ce qu'il comprend
des granules de triazine trione chlorée de formule:

dans laquelle X représente CI, Na ou K, ou le dihydrate de la triazine trione de formule
(I) quand X représente Na, lesdits granules ayant une dimension d'environ 0,5 à 5
mm et étant revêtus d'une mince couche hydrophobe d'un diester de l'acide phtalique
ou de l'acide adipique avec un alcool ayant 4-18 atomes de carbone, et une quantité
de 3-9% en poids, calculée par rapport à la quantité de la triazine trione chlorée
de formule (1).
7. Agent selon la revendication 6, caractérisé en ce que l'alcool est un alcool linéaire
ou ramifié ayant 6-12 atomes de carbone.
8. Agent selon la revendication 6, caractérisé en ce que la couche hydrophobe comprend
une fraction de diesters de l'acide phtalique et d'alcools ayant 6-10 atomes de carbone,
le phtalate de bis(2-éthylhexyl), le phtalate de diisodécyle, l'adipate de bis(2-éthylhexyl)
et/ou l'adipate de diisodécyle.